Synopsis of Some Recent Tactical Application of Bioisosteres in
Transcription
Synopsis of Some Recent Tactical Application of Bioisosteres in
PERSPECTIVE pubs.acs.org/jmc Synopsis of Some Recent Tactical Application of Bioisosteres in Drug Design Nicholas A. Meanwell* Department of Medicinal Chemistry, Bristol-Myers Squibb Pharmaceutical Research and Development, 5 Research Parkway, Wallingford, Connecticut 06492, United States 1. INTRODUCTION The concept of isosterism between relatively simple chemical entities was originally contemplated by James Moir in 1909, a notion further refined by H. G. Grimm’s hydride displacement law and captured more effectively in the ideas advanced by Irving Langmuir based on experimental observations.1-3 Langmuir coined the term “isostere” and, 18 years in advance of its actual isolation and characterization, predicted that the physical properties of the then unknown ketene would resemble those of diazomethane.3 The emergence of bioisosteres as structurally distinct compounds recognized similarly by biological systems has its origins in a series of studies published by Hans Erlenmeyer in the 1930s, who extended earlier work conducted by Karl Landsteiner. Erlenmeyer showed that antibodies were unable to discriminate between phenyl and thienyl rings or O, NH, and CH2 in the context of artificial antigens derived by reacting diazonium ions with proteins, a process that derivatized the ortho position of tyrosine, as summarized in Figure 11,2,4,5 The term “bioisostere” was introduced by Harris Friedman in 1950 who defined it as compounds eliciting a similar biological effect while recognizing that compounds may be isosteric but not necessarily bioisosteric.6 This notion anticipates that the application of bioisosterism will depend on context, relying much less on physicochemical properties as the underlying principle for biochemical mimicry. Bioisosteres are typically less than exact structural mimetics and are often more alike in biological rather than physical properties. Thus, an effective bioisostere for one biochemical application may not translate to another setting, necessitating the careful selection and tailoring of an isostere for a specific circumstance. Consequently, the design of bioisosteres frequently introduces structural changes that can be beneficial or deleterious depending on the context, with size, shape, electronic distribution, polarizability, dipole, polarity, lipophilicity, and pKa potentially playing key contributing roles in molecular recognition and mimicry. In the contemporary practice of medicinal chemistry, the development and application of bioisosteres have been adopted as a fundamental tactical approach useful to address a number of aspects associated with the design and development of drug candidates.1,2,7-13 The established utility of bioisosteres is broad in nature, extending to improving potency, enhancing selectivity, altering physical properties, reducing or redirecting metabolism, eliminating or modifying toxicophores, and acquiring novel intellectual property. In this Perspective, some contemporary themes exploring the role of isosteres in drug design are sampled, with an emphasis placed on tactical applications designed to solve the kinds of problems that impinge on compound optimization and the long-term success of drug r 2011 American Chemical Society Figure 1 candidates. Interesting concepts that may have been poorly effective in the context examined are captured, since the ideas may have merit in alternative circumstances. A comprehensive cataloging of bioisosteres is beyond the scope of what will be provided, although a synopsis of relevant isosteres of a particular functionality is summarized in a succinct fashion in several sections. Isosterism has also found productive application in the design and optimization of organocatalysts, and there are several examples in which functional mimicry established initially in a medicinal chemistry setting has been adopted by this community.14 2. CLASSICAL AND NONCLASSICAL BIOISOSTERES Classical bioisosteres represent the results of an early appreciation of the concept and encompass structurally simple, mono-, di-, and trivalent atoms or groups and ring equivalents that are summarized in the upper half of Table 1.2 In contrast, nonclassical bioisosteres extend the concept to structural elements that offer a more subtle and sophisticated form of biochemical mimicry, relying upon functionality that can differ quite substantially in electronic, physicochemical, steric, and topological representation from that being emulated.2 3. RECENT APPLICATIONS OF ISOSTERES IN DRUG DESIGN 3.1. Isosteres of Hydrogen. 3.1.1. Deuterium as an Isostere of Hydrogen. Substituting a H atom by D represents the most Received: October 20, 2010 Published: March 17, 2011 2529 dx.doi.org/10.1021/jm1013693 | J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry Table 1. Classical and Nonclassical Bioisosteres classical bioisosteres PERSPECTIVE Table 2. Representative Examples of the Effect of Deuteration on the Basicity of Amines and on the Acidity of Carboxylic Acids monovalent bioisosteres D and H F and H NH and OH RSH and ROH F, OH, NH2 and CH3 Cl, Br, SH and OH C and Si bivalent biososteres in which two single bonds are affected CdC, CdN, CdO, CdS -CH2-, -NH-, -O-, -SRCOR0 , RCONHR0 , RCOOR0 , RCOSR0 trivalent bioisosteres in which three bonds are affected R3CH, R3N R4C, R4Si, R4Nþ alkene, imine -CHdCH-, -S-CHd and -NdC nonclassical bioisosteres are structurally distinct, usually comprise different number of atoms and exhibit different steric and electronic properties compared to the functionality being emulated have been divided into two subgroups:2 1. cyclic and noncyclic isosteres 2. exchangeable group isosterism in which the properties of discrete functional elements are emulated conservative example of bioisosterism given the similarities between the two isotopes, but there are circumstances in drug design where this change can offer a significant advantage. The differences in physical chemical properties between H and D are small but measurable: D is slightly less lipophilic than H, Δ log Poct = -0.006;15 the molar volume of D is smaller than H by 0.140 cm3/mol per atom; and C-D bonds are shorter than C-H bonds by 0.005 Å. The progressive deuteration of alkanes commensurately reduces lipophilicity, which can be measured by reduced affinity for hydrophobic surfaces,16 an effect that has been utilized to resolve enantiomers possessing chirality engendered only by virtue of H/D isotopic substitution.17 Incorporation of a D atom slightly increases the basicity of amines in a nonadditive fashion that shows dependence on stereochemical disposition,18-20 while the acidity of phenols and carboxylic acids is decreased by up to 0.031 pK units per D atom.21 Representative data are captured numerically in Table 2.18-21 3.1.2. Deuterium Substitution to Modulate Metabolism. Intermolecular interactions between drug molecules and proteins are also altered by D/H exchange, although the effect is usually modest and dependent on the site of incorporation, particularly with respect to heteroatoms.22 Nevertheless, measurable effects have been observed, as exemplified by the deuteration of the cGMP phosphodiesterase V inhibitor sildenafil which affects enzyme inhibitory selectivity by 2- to 5-fold.23 The primary use of D as an isostere of H in drug discovery has historically focused on taking advantage of the kinetic isotope effect (KIE) to assist in the elucidation of metabolic pathways of drug molecules.24-26 However, an appreciation of the KIE has led to a heightened awareness that deuteration can be a useful strategy to improve the pharmacokinetic properties of drug candidates when incorported at sites relevant to metabolic modification and the first clinical studies with deuterated analogues of known drugs have recently been initiated.27-29 The KIE for D typically ranges from 1- to 7-fold, depending on the circumstance, although calculations suggest a 7- to 10-fold effect and it can be as high as 16-fold.30 Consequently, the strategic deployment of D at sites of metabolism where H atom abstraction is the rate determining step can impede metabolism and redirect metabolic pathways, the latter a potentially useful approach to reducing toxicicty.25,26 SD254 (1) is a deuterated form of venlafaxine, the first dual serotonin/norepinephrine reuptake inhibitor to be approved for the treatment of depression, that incorporates deuterium at the primary metabolic sites.31 Venlafaxine is subject to O-demethylation as the major metabolic pathway, with N-demethylation playing a secondary role, and is a substrate of the polymorphic enzymes CYP 2D6 and 2C19.31,32 Deuteration reduces the rate of metabolism of 1 in vitro by 50%, and early clinical studies indicate increased exposure of the parent drug, reduced exposure of the O-demethyl metabolite, and less variability in the ratio of the O-demethyl metabolite to parent drug.33 CTP-347 (2), a deuterated version of the antidepressant paroxetine,34,35 relieves the mechanism-based inhibition of CYP 2D6 in vitro associated with the methylenedioxy moiety36,37 and preserves enzyme function in normal healthy volunteers following oral dosing.35 3.1.3. Deuterium Substitution To Modulate Metabolism and Toxicity. Perdeuteration of the allylic methyl groups of pulegone (3) attenuated the hepatotoxicity seen in mice with the protio analogue, attributed to a reduction in the extent of CYP 450-mediated allylic oxidation to 4, a precursor to 2530 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE the furan metabolite 6 that undergoes further metabolic activation to the species that appears to be the ultimate source of hepatotoxicity.25 The HIV-1 non-nucleside reverse transcriptase inhibitor (NNRTI) efavirenz (7) is subject to a complex and unique metabolic pathway in rats that ultimately affords the nephrotoxic glutathione-derived conjugate 11. The introduction of deuterium at the labile propargylic site reduced the formation of cyclopropylcarbinol 9 in vivo, reflected in lowered excretion of 11 in urine and a reduction in both the incidence and severity of nephrotoxicity.38 Figure 2 Table 3. Stability of Deuterated 12 toward Racemization in Vitro in Buffer and Plasma kinetic isotope effect (kH/kD) 3.1.4. Deuterium to Slow Epimerization. An interesting application of the deuterium isotope effect has been described for the mechanism-based HCV NS3 protease inhibitor telaprevir (12).39 The (S)-R-ketoamide in 12 readily racemizes at higher pH and, most notably, in human plasma to afford the(R)diastereomer, which exhibits 30-fold weaker biological activity (Figure 2). The (R)-diastereomer of 12 is the primary metabolite in vivo, accounting for 40% of the drug concentration after oral dosing. Deuteration at the labile center afforded D-12 which exhibited a Ki of 20 nM, comparable to that of H-12, Ki = 44 nM, and showed increased stability toward racemization in rat, dog, and human plasma compared to the protio form (Table 3). In human plasma, the deuterated analogue of 12 produced only 10% of the epimer over 1 h compared to 35% for the protio version of 12. In rat plasma, the increase in stability was more modest but the effect translated into a 13% increase in the AUC for the deuterated compound compared to 12 following oral administration to rats and the clearance pathway was not dominated by racemization.39 3.1.5. Fluorine as an Isostere of Hydrogen. The unique properties of fluorine have led to its widespread application in drug design as an isostere for hydrogen, since incorporation of this halogen can productively modulate a range of properties of interest to medicinal chemists.40-46 A survey of 293 pairs of molecules in the Roche compound collection that differed only by a F-for-H exchange revealed that the average lipophilicity (log D) increased by 0.25 log units, reflecting the π coefficient of 0.14 measured for F.41 Perhaps not surprisingly, the histogram of the results exhibited a Gaussian distribution; however, the tail of the plot extended below medium initial relative rate of epimerizaton of H-12 1 μM 10 μM buffer, pH 7.4 rat plasma 1 1.0-1.5 5 7 6 7 dog plasma 1.4-3.4 human plasma >8 4 6 >5 >5 Figure 3. Fluorine-containing fragments associated with increased hydrophilicity compared to the hydrogen-substituted analogues. zero, indicating that in some structural environments, substitution of H by F reduced the overall lipophilicity of a molecule. A closer inspection of these compounds revealed recurring structural themes, with the observation that in all cases there was a low energy conformation in which the F was proximal to an O atom, with an F to O distance of <3.1 Å. The most prominent structural fragments are summarized in Figure 3. However, the origin of the effect is not understood and has been attributed to either an overall increase in polarity, leading to a gain in solvation energy in polar compared to nonpolar medium, or the F-induced polarization of the proximal O atom, leading to stronger H-bonds in a polar solvent.41 3.1.6. Fluorine for Hydrogen Exchange To Modulate Metabolism. Early applications of the exchange of H by F focused on the regiospecific deployment of fluorine to interfere with metabolic processes, a tactic that relies on the powerful electron withdrawing properties of F and the strength of the C-F bond which, at approximately 108 kcal/mol, is the strongest known between C and any other atom.40-46 This renders the C-F bond chemically inert under most biological conditions, although metabolic activation of fluoroacetic acid47 and sorivudine (5fluorouracil)48 are notable exceptions. Fluorine also increases the strength of adjacent C-F, C-O, and C-C bonds but interestingly 2531 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry does not exert much influence on the strength of proximal C-H bonds. The introduction of two fluorine atoms into the cholesterol absorption inhibitor 13 was a critical step toward increased metabolic stability, ultimately optimized in the context of PERSPECTIVE Table 4. Effect of Introduction of Proximal F Atoms on the Basicity of Amines and the Acidity of Carboxylic Acids amine pKa acid CH3CH2NH3þ CH2FCH2NH3þ CHF2CH2NH3þ CF3CH2NH3þ pKa 10.7 CH3CO2H 4.76 9.0 7.3 CH2FCO2H CHF2CO2H 2.66 1.24 5.7 CF3CO2H 0.23 analogue 21 was prepared as a tool to probe the role of metabolism in the psychopharmacology and neurotoxicity associated with the use of 20, although detailed biological studies that would validate the concept have not been reported.56 ezetemibe (14), marketed as Zetia.41,49 In contrast, the fluorinated cyclooxygenase inhibitor 15 is the close analogue of a compound that exhibited an undesirably long half life of 221 h in vivo in the rat, precipitating examination of the CH3 moiety as a replacement for the F atom as a means of introducing a metabolic soft spot, a prelude to the identification of celecoxib (16).41,50 A CF3 substituent introduced to replace a CH3 bound at the 5-position of a 1,2,4-oxadiazole ring provided a consistent increase in global metabolic stability in a series of picornavirus entry inhibitors that resulted in the identification of pleconaril (17), a compound advanced into clinical evaluation.51 The origin of this effect is not well understood but has been observed with other molecules,52-54 although in the case of 17 the effect was not unique to CF3, since cyclopropyl, CHF2, OEt, and CONH2 also increased metabolic stability in vitro while interestingly CH2CHF2 and CH2CF3 did not.51 Substituting O-CH2-O with O-CF2-O in benzo[d][1,3]dioxole derivatives interferes with cytochrome P-450mediated metabolic activation of this naturally prevalent moiety to a carbene, a process associated with the formation of problematic CYP 450 metabolic intermediate complexes (MI complexes).36 A productive example is provided by the favorable in vivo performance of the camptothecin derivative 18 following administration of the prodrug 19, with the O-CF2-O moiety introduced to enhance metabolic stability.55 A similar tactic has been explored as an approach to reducing metabolism of methylenedioxymethamphetamine (20, MDMA), better known as ecstasy, a drug of abuse. The difluoro 3.1.7. Deploying Fluorine To Modulate Basicity in KSP Inhibitors. The high electronegativity of F reduces the basicity of proximal amines while increasing the acidity of acids (data summarized quantitatively in Table 4).43 The strategic deployment of a fluorine atom to modulate basicity was probed in the context of inhibitors of kinesin spindle protein (KSP), a family of motor proteins that represents a novel mechanistic target for the treatment of taxane-refractory solid tumors.57 Optimization of a dihydropyrrole-based series of KSP inhibitors identified 22 as an advanced molecule in which the CH2OH moiety was introduced to diminish hERG binding.57 Variation of the piperidine N-substituent focused on those reducing basicity to a pKa in the range 6.5-8.0, which had been determined experimentally to reduce PgP efflux in a tumor cell line. The Ncyclopropyl moiety found in 22 aligned basicity in the targeted range but conferred time-dependent CYP P450 inhibition, a phenomenon well-known with cyclopropylamines.58 A fluoroethyl substituent performed similarly, but 23 was dealkylated in rat liver microsomes (RLM) as the major metabolic pathway to afford 24 and fluoroacetaldehyde, which was oxidized to fluoroacetic acid. The toxicological effects observed in vivo were consistent with release of fluoroacetic acid, a highly toxic substance that enters the tricarboxylic acid cycle and irreversibly inhibits the enzyme aconitase.47,59 An effective solution was found by deploying the F substituent in the piperidine ring where the effect on pKa was dependent on stereochemical disposition. In the trans analogue 26, the F adopts an equatorial position that leads to a 2 log10 reduction in basicity from pKa = 8.8 to pKa = 6.6. In contrast, in the cis isomer 25 the F is disposed axially, expected on the basis of the substituent A values and confirmed by X-ray crystallography, producing a more modest 1.2 log10 effect on basicity, pKa = 7.6. This compound, MK-0731 (25), was subsequently advanced into clinical trials.57 2532 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 5. Calculated Conformational Preferences for R-Fluorocarbonyl Derivatives Figure 4. Coformational preferences for 28 and 29. Figure 5. Preferred conformation of benzyl fluoride. 3.1.8. Substitution of Hydrogen by Fluorine as a Strategy for Influencing Conformation. As a consequence of the high electronegativity of F, the C-F bond is the most polarized in organic chemistry, producing a large dipole (1.85 D for methyl fluoride) that can influence conformational bias via intramolecular electrostatic interactions with other dipolar bonds, including CdO and C-F moieties.46 For example, R-fluorinated carbonyl derivatives favor a conformation in which the C-F and CdO bonds adopt a trans orientation to align the dipoles in an antiperiplanar, 180° topology, a preference that correlates with the strength of the carbonyl dipole, as summarized in Table 5.46,59-62 The energetics of interaction of a wide range of substituents common in drug design with the C-F moiety in 2-substituted fluoroethane have been calculated using density functional theory (DFT) in order to quantitatively assess the influence of this gauche effect on conformational preferences.46,63-66 The data are summarized in Table 6, which includes the authors’ comments attributing the underlying source of the interaction, a function of either positive electrostatic interactions between F and X, a productive hyperconjugation between the σ* of the C-F or C-X bond and the C-H bond on the adjacent atom, or a repulsion between the electronegative F and X substituents.63 For NH3þ, OCHO, NO2, NHCHO, F, N3, and NdCdO, polarization leads to a productive σ(C-H) f σ*(C-X) interaction that further stabilizes the gauche conformation.63 This preference of a fluorine atom to favor a gauche conformation with an adjacent substituent has been exploited in drug design in a striking example that illuminated aspects of biological recognition in the context of the neurotransmitter γ-aminobutyric acid (27, GABA).67 The two enantiomers of 3-fluoro-GABA, (R)-3-F-GABA (28) and (S)-3-F-GABA (29), were synthesized, an isosteric substitution that reduced the basicity of the amine while increasing the acidity of the acid, as would be anticipated (pKa’s of 28 and 29 = 8.95 and 3.30; pKa’s of 27 = 10.35 and 4.05) (Figure 4). However, fluorine substitution preserved the zwitterionic nature of the molecule at neutral pH and an extended conformation was found to predominate in solution by 1H NMR analysis, favored by the gauche interaction Table 6. Calculated Energy Differences between the gauche and anti Conformers of F-CH2-CH2-X X Δ energy Δ energy gauche-anti gauche-anti preferred between the gauche and (kcal/mol) B3LYP (kcal/mol) M05-2X conformer anti conformers (D) difference in dipole underlying interaction -NH3þ -6.65 -7.37 strong gauche Not applicable electrostatic F δ- and NH3þ δþ -O-CdO.H -NO2 -1.40 -1.22 -2.18 -1.12 strong gauche strong gauche 4.94 4.42 electrostatic C-F δ- and CdO C δþ antiparallel δ-FC-H and N δþ-O δ-; F δ- and N -NHCdO.H -1.00 -1.12 strong gauche 4.53 electrostatic C-F δ- and N δþ -F -0.82 -0.66 strong gauche 3.02 σC(F)-H to σ*C-F -N3 -0.76 -1.21 strong gauche 3.42 electrostatic C-F δ- and central N δþ -NdCdO -0.74 -1.06 strong gauche 3.97 electrostatic C-F δ- and CdO C δþ -CHNH -0.25 -0.65 strong gauche 3.62 -CHCCH2 -0.19 -0.34 weak gauche 2.00 -CH3 -CHCH2 -0.18 -0.01 -0.35 -0.17 weak gauche weak gauche 2.11 1.95 -CtN 0.64 -0.64 strong anti 4.68 p orbital repulsion -CHO 0.84 -1.20 strong anti 3.82 p orbital repulsion and antiparallel dipole: 2.18 CdOδ- 3 3 3 δþHCF δp orbital repulsion -CtCH 0.98 -1.03 strong anti 2533 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry between F and NH3þ (Figure 4).67 Each enantiomer interacted similarly with the GABAA receptor, but the (S)-isomer 29 exhibited higher affinity for GABA transaminase than the (R)isomer 28. This led to the conclusion that the extended conformer B in Figure 4 is recognized by the GABAA receptor but conformer A, in which the NH3þ and acid are in a gauche relationship and which is disfavored in the (R)-isomer 28, is recognized by the transaminase.67 An additional consequence of the highly polarized C-F bond is a low lying σ*C-F antibonding orbital that is available for hyperconjugative interactions and that can also influence conformational preferences.46,63,68 This orbital is available to stereoelectronically aligned donor orbitals, including C-H and π bonds as well as O and N lone pairs, all of which have been shown to contribute to the stabilization of select conformations.46,63 For example, the modestly preferred (∼0.4 kcal mol-1) conformation of benzyl fluoride projects the C-F bond orthogonal to the aryl ring, stabilized by donation of electron density from the aryl π-orbital into the σ*C-F antibonding orbital, as depicted in Figure 5.69 The conformational preferences of vicinal fluoroalkanes provides another interesting opportunity to exploit the effects of replacing H by F, taking advantage of the preference for fluorines on adjacent carbons to adopt a gauche relationship. This approach to conformational bias is based on stabilization by a combination of favorable dipole-dipole, electrostatic, steric, and hyperconjugative interactions (Table 6).46,63,70-72 The replacement of a hydrogen atom that is in proximity to an amide NH with a fluorine has been shown to result in interesting effects on biological properties in several systems. In these examples, the preference for an antiperiplanar alignment of dipoles is augmented by a productive interaction between the NH and F atoms, a relationship that has been described as electrostatic in nature rather than a true H-bond. An appreciation of this effect formed the basis of an attempt to elucidate the conformational preferences of capsaicin (30) when bound to the transient receptor potential vanilloid 1 (TRPV1) receptor.73 The enantiomers of R-fluorocapsaicin (31) were synthesized in optically pure form, with the trans conformation depicted in Figure 6 calculated to be favored by 6 kcal mol-1 over the gauche conformation and by 8 kcal mol-1 over the cis conformation, stabilized by the C-F/CdO dipole and an electrostatic interaction between F(δ-) and NH (δþ). This preference would influence the topographical projection of the alkylene side chain of the individual enantiomers, providing a potential opportunity to assess any subtleties with respect to the preferred conformation of 30 at the receptor, as depicted in Figure 7. However, the study was not definitive, since both enantiomers of 31 performed similarly as agonists at the TRPV1 receptor, suggesting that the bound conformation is an extended form readily accessible to both enantiomers.73 3.1.8. Fluorine/Hydrogen Exchange To Modulate Potency. It is well-documented that the judicious substitution of H by F can exert substantial effects on potency.40,74-76 In the quinolone series of antibacterial gyrase inhibitors represented by 32, a F substituent at PERSPECTIVE Figure 6. Conformational preferences of 2-fluoro-N-methylpropanamide. Figure 7. Preferred conformation of 31 and the implication for side chain projection in the two enantiomers. C-6 improves potency by 2- to 7-fold, measured as binding to the enzyme, increases cell penetration up to 70-fold, reduces plasma protein binding, and improves the pharmacokinetic profile.40,74 In the oxazolidinone antibacterial class, a strategically deployed F atom increases potency and efficacy in vivo and is incorporated into the marketed compound linezolid (33).40,75 For inhibitors of HIV-1 attachment, compounds that interfere with the interaction between viral gp120 and host cell CD4, the 4-fluoroindole 35 exhibits a more than 50-fold increased potency compared to the unsubstituted 34, although in this particular example Cl and Br also led to improved potency.76 3.1.9. Fluorine/Hydrogen Exchange To Influence Membrane Permeability. In two structurally related series of anilide-based factor Xa inhibitors, a F for H exchange ortho to the NH improves Caco-2 cell permeability (data compiled in Table 7).77,78 This effect may be due to an electrostatic interaction between the C-Fδ- and N-Hδþ that effectively masks the H-bond, a contention supported by the inability of the linear nitrile to exert a similar effect in the aminobenzisoxazole series. A fluorine atom proximal to an amide N-H is a motif found in a number of kinase inhibitors where a similar effect may be operative, since oral exposure is often improved, although without the appropriate data it cannot be concluded that this is simply a function of improved membrane penetration. Two examples culled from the literature include the matched pair of F-associated kinase inhibitors 36 and 3779 and the multitargeted kinase inhibitors 38 and 39.80 In addition to the anilide motif presented in Table 7 and depicted as motif A in Figure 8, a fluorine atom ortho to a benzamide (Figure 8, motif B) is a commonly occurring structural element, offering a potentially similar electrostatic interactive effect. Although this might be anticipated to be a somewhat weaker interaction, it may nevertheless be sufficient to mask the NH and improve membrane 2534 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 8. Comparison of the Physical Properties of O, CH2, and S Figure 8. Fluorinated acetanilide and benzamide motifs. Table 7. Caco-2 Permeability for Two Related Series of Factor Xa Inhibitors 3.2.2. CH2/O Isosterism in PGI2 Mimetics. Prostacyclin (42, PGI2) is a naturally occurring arachidonic acid metabolite that is both a potent inhibitor of blood platelet aggregation and vasodilator but that is chemically unstable as a result of the hydrolytically sensitive enol ether moiety. Replacing the ether O atom of 42 with CH2 resolved the hydrolytic lability while modifying the β-side chain restored potency, affording iloprost (43) as a PGI2 mimetic with a profile similar to that of the natural compound.84 Compound 43 is orally bioavailable in humans but has a biological T1/2 of only 20-30 min, with β-oxidation of the carboxylic acid moiety identified as the primary metabolic pathway. This process proceeds through the CoA ester which is dehydrogenated prior to the Michael addition of water, a reaction pathway that can be interrupted by several tactical structural modifications including R- and/or β-disubstitution or the introduction of a heteroatom to replace the β-carbon.85 The latter approach, in conjunction with further manipulation of the β-side chain, was pursued to realize cicaprost (44), a molecule that demonstrated hypotensive activity in rats lasting 2-3 times longer than 43.84 permeability, and this constellation of functionality is represented in several clinically advanced molecules. Prominent examples include ZD-9331 (40), a fluorinated analogue of methotrexate that shows activity toward ovarian cancer cells resistant to classical thymidylate synthase inhibitors,81 and the antiandrogen MDV-3100 (41), currently in phase 3 clinical trials for the treatment of castration-resistant prostate cancer.82,83 The latter exhibits excellent PK, with the implication that the F has a positive impact, although there are no specific data on the PK properties of the protio analogue presented that would allow direct comparison. 3.2. Isosteres of Carbon and Alkyl Moieties. 3.2.1. CH2, O, and S Isosterism. The comparative properties of the classical bivalent isosteres CH2, O, and S are summarized in Table 8, which reveals both notable similarities and some marked differences that have the potential to be influential in exercises in drug design. 3.2.3. CH2/O Isosterism in Non-Prostaonid PGI2 Mimetics. An interesting effect of CH2/O isosterism was reported in a series of lipophilic carboxylic acid derivatives that function as partial agonists at the PGI2 receptor and that are effective inhibitors of blood platelet aggregation in vitro in platelet-rich plasma.86,87 The series originated with the discovery that octimibate (45) is a PGI2 receptor partial agonist, a molecule optimized to afford BMY-45778 (48) via the 2535 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry intermediacy of the simpler diphenyloxazoles 46 and BMY-42393 (47), part of a progression leading to the elucidation of pharmacophore topography.86 A systematic survey of the effects of interchanging CH2 and O in both two-atom linker elements of 47, summarized in Table 9, revealed that a OCH2CO2H terminus was >10-fold superior to the analogous CH2CH2CO2H (compare 47 with 49 and 51 with 52), while the trans acrylic acid moiety found in 50 and 53 exhibited equivalent-fold to-10-fold inferior potency to the OCH2CO2H analogues 47 and 51.87 Thus, the presence of atoms able to interact with the π system improves potency over the simple CH2CH2 linker element. This result may be understood in the context of the preferred conformations adopted by these moieties, summarized in Figure 9, that directs some caution when contemplating the introduction of heteroatoms as CH2 isosteres when these are directly attached to π systems.87-91 Both the OCH2CO2H (Figure 9A) and trans CHdCH-CO2H (Figure 9B) moieties preferentially adopt a coplanar arrangement with the phenyl ring, a consequence of interaction between the lone pair on oxygen and the π-system of the aromatic ring or the π-system of the olefin and the phenyl ring, sufficient to surmount A1,3 strain in the latter.88-93 In examples in the Cambridge Structural Database (CSD), Ar-O-CH2 angles are distorted just 2-20° from the plane of the aromatic ring and 30/32 anisole derivatives in the CSD exhibit a dihedral angle of 6 ( 6° and a C-C-O angle of 124°, indicative of significant rehybridization to accommodate the lone pair-π interactions.89 In contrast, the CH2CH2CO2H moiety preferentially adopts a projection orthogonal to the Ph ring in order to avoid A1,3 strain with the ortho hydrogen atoms (Figure 9C).93 Interestingly, in this PGI2 mimetic series the effect of exchange of CH2 and O at the oxazole-CH2-CH2-Ar juncture is muted, perhaps because this is sufficiently remote from the carboxylic acid terminus and in a region where structural variation may be more readily accommodated (Table 9).87 Table 9. Structure-Activity Relationships for Blood Platelet Aggregation Inhibition in Platelet-Rich Plasma by a Series of Non-Prostanoid PGI2 Mimetics PERSPECTIVE Figure 9. Preferred conformations of phenoxyacetic, cinnamic, and β-phenylpropionic acid derivatives. Table 10. Structure-Activity Relationships for a Series EP3 Receptor Antagonists An example in which CH2/O exchange had an opposing effect on potency occurred in the series of EP3 receptor antagonists 54-59 compiled in Table 10.94 PGE2 acts through several GPCRs, and the EP3 receptor subtype is of importance in the regulation of ion transport, GI smooth muscle contraction, acid secretion, uterine contraction during fertilization and implantation, fever generation, and PGE2-mediated hyperalgesia. In the selective EP3 receptor antagonists 54-59, potency was highly sensitive to the identity of the linker atom between the naphthalene and phenyl rings, with CH2 (54) optimal and both S (56) and SO2 (58) acting as useful surrogates. However, an oxygen atom linker (55) led to an almost 150-fold erosion in potency, attributed to conformational effects that restrict the optimal topographical deployment of the naphthalene ring. 94 Interestingly, the marked serum effect noted was subsequently reduced by modification of the substitution pattern of the thiophene ring. 3.2.4. Silicon as an Isostere of Carbon A Comparison of the Properties of Silicon and Carbon. Silicon has been probed as an isostere of carbon in the context of a number of bioactive molecules, and several compounds have been advanced into clinical studies, while the antifungal flusilazole (60) and pyrethroid insecticide silafluofen (61) are siliconcontaining molecules with broad commercial application in agriculture.95-99 The use of silicon as an isostere of carbon ranges from the simple, structurally benign replacement of an alkyl moiety by trialkylsilyl to the more sophisticated design of silanediol (Si(OH)2) as a transition state mimetic in protease inhibitors and the application of Si-OH as a replacement for C-OH in circumstances where this may offer a specific advantage. The metabolism of silicon-containing molecules appears to follow predictable pathways, with the susceptibility of Si dealkylation similar to that of more conventional heteroatoms, and no unusual Si-related toxicities have been identified to date. 2536 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 11. Comparison of Key Physical Parameters Associated with Carbon and Silicon carbon silicon covalent radius 77 pm 117 pm bond length C-C is 1.54 Å Si-C is 1.87 Å electronegativity 2.50 1.74, more electropositive than C, N, O lipophilicity Ph-t-Bu: cLogP = 3.97 Ph-Si(CH3)3: cLogP = 4.72 bond stability C-H stable Si-H labile particularly under basic conditions C-O-C stable Si-O-C hydrolytically sensitive C-OH stable Si-OH stable but liable to condensation; usually more acidic than C-OH C-N stable CdC and CtC stable Si-N hydrolyses under acidic conditions SidSi and SitSi are unstable Table 12. Comparative in Vitro Data for the p38R Mitogen-Activated Protein (MAP) Kinase Inhibitor 62 and the Silicon Analogue 63 62 63 pKa 1.9, 6.4 2.3, 6.3 log P 5.2 4.7 log D (pH 7.4) 5.1 4.7 IC50 (nM) 55 64 HLM (% turnover after 40 min) 79 62 The properties of Si and C are compared in Table 11 where the most notable differences are the increased covalent radius of Si, 50% larger than for C, the 20% longer C-Si bond length, and the higher lipophilicity of Si derivatives. The two atoms also demonstrate some complementarity in both physical properties and chemical stability when bound to heteroatoms, properties that can be exploited in drug design, as illustrated below with select examples from the literature. 3.2.5. Silicon in p38R MAP Kinase Inhibitors. The substitution of a tert-butyl moiety in the p38R mitogen-activated protein (MAP) kinase inhibitor doramapimod (62, BIRB-796) by a trimethylsilane is an effective example of a straightforward bioisosteric substitution of a silicon for a carbon atom.99 The Si-for-C switch slightly increased the pKa of the morpholine N atom, atypically reduced overall lipophilicity, and had no significant effect on metabolic stability (data summarized in Table 12). In a mouse model of LPS-induced TNFR release, sila-BIRB-796 (63) exhibited efficacy comparable to that of the progenitor following an oral dose of 10 mpk.99 3.2.6. Silicon as a Carbon Isostere in Biogenic Amine Reuptake Inhibitors. The dual serotonin and noradrenaline reuptake inhibitor venlafaxine (64), marketed as the racemic mixture (Effexor) for the treatment of depression, provided an interesting opportunity to deploy Si as a C isostere in a more strategic fashion designed to influence biological and physical properties.100-102 The essential properties of racemic sila-venlafaxine (65) and the resolved enantiomers are compared with the analogous carbon compounds in Table 13, data that reveal some marked differences. Although log P, log D, and the pKa of 64 and 65 are similar, racemic 64 is a potent inhibitor of SERT/NET, (S)-64 is 100-fold selective for SERT over NET, whereas (R)-64 is a more balanced SERT and NET inhibitor.100-102 Compound 65 retains NET and DAT but sacrifices SERT, while (R)-65 is much less potent, with no selectivity for SERT and DAT but 10-fold selective for NET. Thus, the in vitro profiles of the individual forms of 65 are quite different from the carbon analogues. (R)-65 expresses antiemetic activity in rats following oral dosing of 5 mpk. 3.2.7. Silicon as a Carbon Isostere in Haloperidol. The tertiary alcohol of the dopamine D2 antagonist haloperidol (66, Table 14), a clinically useful antipsychotic agent, is associated with a problematic metabolic pathway that was recognized as an opportunity to demonstrate the potential of the analogous silanol 67 to mitigate a potential toxicity issue.103 Compound 67 is slightly more basic than 66 and exhibits modest changes in receptor affinity that amplify the dopamine D2 selectivity (data compiled in Table 14). The other properties reported for the two molecules are very similar with the exception that 67 is a 3-fold more potent inhibitor of CYP 3A4 than 66. Compound 66 is metabolized in part by dehydration of the tertiary alcohol to afford 68 which is readily oxidized to the pyridinium 69, a neurotoxin related to the pyridinium derived from 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) that is suspected as a source of parkinsonism in the clinic (Figure 10).104 It was anticipated that 67 would not be subject to an analogous metabolic pathway to produce 70 and 71 because CdSi bonds are inherently unstable.103 Indeed, the metabolism of 67 in HLM, elucidated by MS, is quite different from haloperidol, with no dehydration of the silanol moiety observed, as predicted (Figure 11).103,105 The major metabolic pathways for 67 involve hydroxylative ring-opening of the sila-piperidine ring, a pathway not observed with 66, in addition to N-dealkylation. Interestingly, the silanol moiety was not subject to glucuronidation, a significant metabolic pathway for 66, leading to the suggestion that the silanol functionality may offer an opportunity to introduce a hydrophilic element resistant to this phase II metabolic modification.105 More recently, the sila analogue 79 of the related dopamine D2 2537 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 13. Comparison of the Properties of Racemic 65 and the Resolved Enantiomers with the Analogous Carbon Compounds rac-venlafaxine (64) (R)-venlafaxine (S)-venlafaxine rac-sila-venlafaxine (65) (R)-sila-venlafaxine (S)-sila-venlafaxine SERT IC50 (μM) 0.020 0.030 0.007 1.063 3.168 0.791 NET IC50 (μM) 0.149 0.061 0.754 0.109 0.251 4.715 DAT IC50 (μM) 4.430 19.600 6.670 2.630 5.270 36.35 pKa 9.7 9.7 log P 3.13 3.21 log D (pH 7.4) 0.88 0.92 Table 14. Comparative in Vitro Data for 66 and 67 minimal effect on D1 binding, reducing the D2/D1 selectivity of 79 to 3-fold.106 3.2.8. Silicon/Carbon Isosterism in Retinoids. The silicon analogues of two retinoid X receptor (RXR) activators, SR11237 (80) and its indane-based homologue 81, were compared with the corresponding disila derivatives 82 and 83, respectively.107,108 In this study, the two ring sizes were probed based on an appreciation of the increased C-Si bond lengths compared to C-C. While the disilane 82 exhibited a slight advantage over the carbon analogue 80, the disilaindane analogue 83 was found to be a 10-fold more potent RXR activator than the carbon analogue 81, providing the first demonstration of increased potency for a silicon switch. An X-ray cocrystal structure revealed additional interactions between 83 and helices 7 and 11 in the RXR protein, providing a potential explanation for the observed potency differences.107,108 Figure 10. Metabolism of 66 compared with the analogous sila analogue 67. Figure 11. Metabolism of 67 in human liver microsomes (HLM). antagonist trifluperidol (78) has been profiled to show that the silicon switch reduced affinity for D2 receptors by 10-fold with 3.2.9. Silicon/Carbon Exchange in Protease Inhibitors. Sieburth has pioneered the exploration and application of silane diols as potentially chemically stable transition state mimetics of a hydrated carbonyl moiety in protease inhibitor design.109 Carbonyl hydration is typically disfavored in the absence of activation by powerful electron withdrawing groups, whereas the silanediol moiety offers diametrically complementary properties, since it will dehydrate only under forcing conditions (Figure 12). Synthetic access to target molecules had to be developed in order to probe these transition state mimetics, and there was concern a priori that the target molecules may be chemically unstable because the simple homologue MeSi(OH)2Me readily polymerizes into siloxane, a process known to decrease in rate as the size of the organic group increases.109 2538 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry Figure 12. Comparison of the hydration equilibrium for the carbonyl and silanone moieties. 3.2.10. Silanediols as HIV-1 Protease Inhibitors. Inhibition of HIV-1 protease was examined initially because it offered a wellestablished class of enzyme inhibitor with extensive existing SAR that would facilitate the appropriate comparisons. The silanediol 84 inhibited HIV-1 protease with Ki = 2.7 nM, which compared favorably to the more conventional secondary alcohol 85, Ki = 0.37 nM, with the modest 7-fold reduction in potency attributed to the increased size of Si and the attendant longer C-Si bonds.109,110 In cell culture, the silanediol 84 exhibited antiviral activity commensurate with enzyme inhibitory activity that was not significantly affected by the presence of human serum.109,110 3.2.11. Silanediols in Angiotensin Converting Enzyme Inhibitors. Angiotensin converting enzyme (ACE) is a Zn2þdependent metalloprotease that is the biochemical target of captopril, the first clinically effective inhibitor of ACE to be marketed. The inhibitory activity of the silanediol-based 86 is just 4-fold weaker than the carbon analogue, ketone 87. However, inverting the two chiral centers adjacent to the Zn2þ-binding element revealed significant differences in potency between the silicon and carbon homologues, with the Si-based 88 more effectively preserving activity than 89, hypothesized to be a function of conformational differences between the two molecules.109,111 3.2.12. Silicon in Thermolysin Inhibitors. Application of the silane diol transition state mimetic was extended to the related Zn2þ-dependent metalloprotease thermolysin for which potent inhibitors are typically based on phosphinic acids. Silicon and phosphorus are second row elements with similar atomic radii, 1.10 and 1.05 Å, respectively, but they are very different electronically. Moreover, their physical properties differ markedly, with phosphinic acids anionic and acidic while silanediols are neutral species at physiological pH. Nevertheless, the silanediol 90 inhibited thermolysin with potency similar to that of the phosphinic acid prototype 91. Determination of the solid state structure of a silanediol/thermolysin cocrystal revealed a similar PERSPECTIVE bound conformation to the analogous phosphinic acid, with a single oxygen atom of the silanediol within bonding distance of the active site zinc.109,112,113 3.2.13. Cyclopropyl Rings as Alkyl Isosteres. Cyclopropyl moieties have been examined as isosteres of alkyl groups based on their size similarity and typically improved metabolic stability. However, prudence is advisible when strategically deploying cyclopropyl moieties because the inherent ring strain can be a source of metabolic activation, well documented in the context of cyclopropyl amines.58 In the series of respiratory syncytial virus (RSV) fusion inhibitors 92-96 compiled in Table 15, the N-isopropenyl (92), N-isopropyl (93), N-tert-butyl (94), and N-cyclobutyl (96) derivatives were characterized as potent antiviral agents but each exhibited poor metabolic stability in human liver microsomes (HLM).114,115 The N-cyclopropyl analogue 95 provided a satisfactory solution, maintaining antiviral activity while uniquely improving metabolic stability. Notably, although the cyclopropyl moiety reduced cLogP by 0.5 compared to isopropyl, Caco-2 cell permeability was maintained and this element was subsequenlty incorporated into a molecule closely related to 95 that was identified with the potential for clinical evaluation.114,115 3.2.14. Cyclopropyl in T-Type Ca2þ Channel Antagonists. In a potent series of quinazoline-based T-type Ca2þ channel antagonists, a cylopropyl moiety was introduced to replace the N-ethyl substituent in lead 97 in an effort to reduce N-dealkylation and improve oral bioavailability (Table 16).116 Although compound 98 successfully addressed the primary deficiency, time-dependent CYP inhibition was introduced as an unacceptable liability, necessitating further optimization. In this setting, the N-CH2CF3 analogues 99 and 100 provided the sought after compromise in properties. 3.2.15. Cyclopropyl in CRF-1 Antagonists. The pyrazolo[3,4-d]pyrimidine derivative 101 is a potent corticotropin releasing factor-1 (CRF-1) receptor antagonist that demonstrates poor metabolic stability in HLM, attributed to the high cLogP (Table 17).117 In an effort to address this problem, the introduction of polarity in the N-1 and C-4 substituents and at other sites of the molecule was examined. This exercise produced 102, a compound that reflected a trend of improved metabolic stability broadly correlating with reduced lipophilicity.117 However, since Table 15. Effect of N-Substituent Variation on the in Vitro Properties of a Series of RSV Inhibitors 2539 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry Table 16. Effect of N-Substituent Variation on the Biochemical Profile of a Series of T-Type Ca2þ Channel Antagonists PERSPECTIVE Table 18. Physical Properties Associated with a Series of Oxetane Derivatives Derived from the Phenylbutylamine 104 Table 17. Structure-Activity Relationships Associated with a Series of Corticotropin Releasing Factor-1 (CRF-1) Receptor Antagonists a HLM = human liver microsomes. b MLM = mouse liver microsomes. Logarithm of octanol/water distribution coefficient at pH 7.4. d Lipophilicity of the neutral base defined by log P = log DpH þ log(1 þ 10(pKa-pH)). c CRF-1 receptor affinity was markedly reduced by the introduction of polar elements, the authors returned to an NCH(cPr)2 moiety at C-4 that had been explored earlier but that had exhibited instability under acidic conditions. However, in this circumstance 103 emerged as an acid-stable CRF-1 antagonist with an acceptable combination of biological properties.117 3.2.16. Oxetanes as Mimetics of Alkyl Moieties. The properties of oxetanes have recently been examined in a systematic fashion and shown to productively influence several properties of interest in drug design, including a role as isosteres of alkyl substituents.118-120 The gem-dimethyl moiety is typically introduced as a conformational constraint, taking advantage of the Thorpe-Ingold effect, or as a strategy to block a site of metabolism. However, a gem-dimethyl substituent typically increases lipophilicity by ∼1 log10 unit compared to the methylene precursor, frequently leading to the adoption of the cyclopropyl element as an isostere that more modestly alters lipophilicity. The oxetane moiety offers an alternative that is essentially liponeutral, affording no net increase in lipophilicity compared to a dihydrogen progenitor that, more importantly, occupies almost the same van der Waals volume as a gem-dimethyl group.118-121 A systematic analysis of the effect of introducing an oxetane ring into a druglike molecule was explored in the context of the phenylbutylamine 104, a prototypical amphiphilic compound poorly soluble in water in the neutral form (Table 18).118-120 The properties of 104 were such that it was a significant inhibitor of the hERG ion channel, IC50 = 7.5 μM, and expressed properties predictive of the potential to cause phospholipidosis. In the homologous series of oxetane derivatives 105-111 summarized in Table 18, the basicity of the amine element was reduced, dependent on proximity to the oxetane ring, while solubility increased in a fashion independent of the site of deployment of the oxetane ring. Moreover, several of these molecules demonstrated increased metabolic stability in human and mouse liver microsomes while compound 110 exhibited diminished hERG inhibition (hERG IC50 = 35 μM) compared to 104 and a reduced theoretical potential to cause phospholipidosis.118,119 3.2.17. CF3 as a Substitute for Methyl in a tert-Butyl Moiety. The CF3 moiety has been explored as a substitute for a CH3 in tertbutyl-substituted antagonists of the neurokinin 1 (NK1) receptor recognized by substance P, agents potentially useful in the treatment of depression and for inducing analgesia, and in antagonists of the TRPV1 receptor, a nonselective cation channel found on peripheral sensory neurons.122 In both cases, the tert-butyl-substituted lead compounds demonstrated poor metabolic stability in vitro with the t-Bu group shown to be susceptible to oxidation. CF3-substituted NK1 homologues retained intrinsic potency and showed reduced clearance in HLM (Table 19) while in TRPV1 antagonists, a simple CF3 substitution led to increased HLM stability but poor biological activity, attributed to the electron withdrawing properties of the CF 3 moiety (Table 20). 122 A key question with respect to the role of the CF3 moiety as an alkyl isostere is its size relative to the groups that it is replacing. The CF3 moiety is frequently considered to be isosteric with an isopropyl group, but Taft’s Es values suggest that CF3 is larger than i-Pr although smaller than t-Bu while the van der Waals volume indicates that CF3 is similar in size to CH3CH2 and smaller than i-Pr (Table 21). In an attempt to resolve this discrepancy, the rotational barriers in ortho-substituted biphenyls have been determined, with the result that in this setting the CF3 substituent is bulkier than a CH3 moiety, comparable to isopropyl and actually larger than (CH3)3Si.42,123 However, the CF3 moiety clearly has a very different topographical shape to an isopropyl group and a recent investigation 2540 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry Table 19. Comparison of the Effects of Substituting a CH3 by CF3 in NK1 Antagonists PERSPECTIVE Table 22. Structure-Activity Relationships Associated with Variation of the Alkyl Side Chain Terminus in a Series of MMP-9 Inhibitors Table 20. Comparison of the Effects of Introducing a CF3 Moiety in TRPV1 Antagonists Table 23. In Vitro Aβ-Reducing Potency and Metabolic Stability of a Series of 2-Oxoazepane-Based γ-Secretase Inhibitors Table 21. Comparison of the Steric Size of Alkyl, CF3, and Silyl Moieties Using Different Methods of Analysis has explored the size of the CF3 group in the context of inhibitors of matrix metalloprotease-9 (MMP-9).124 MMP-9 was considered a useful probe of this concept based on the shallow, tunnellike S10 pocket projecting into a well-defined lipophilic pocket that was viewed as a sensitive probe with which to explore steric effects associated with the side chain terminus of barbituratebased inhibitors. As summarized in Table 22, a methyl and ethyl terminus afforded potent MMP-9 inhibitors but a terminal isopropyl group reduced potency by 1000-fold while a CF3 moiety retained activity, leading to the conclusion that CF3 more closely resembled CH3CH2 rather than i-Pr.124 3.2.18. CF2 as an Isostere of C(CH3)2. An interesting example of the potential of CF2 to function as an isostere of C(CH3)2 has been described in a series of γ-secretase inhibitors that demonstrated a potent Aβ-lowering effect in a cell-based assay.125 As compiled in Table 23, the potency of the prototype 111 was improved 10-fold by gem-dimethyl substitution of the azepinone ring (112), but metabolic stability in human and mouse liver microsomal preparations was poor. The gem-difluoro analogue 113 exhibited improved potency and metabolic stability but was poorly active in a transgenic mouse model of γ-secretase activity, attributed to the two amide functionalities reducing CNS penetration. Optimization to address this issue produced the anisole derivative 114 which retained potency and metabolic stability in HLM and was active in the mouse model at a dose of 20 mpk.125 3.3. N Substitution for CH in Benzene Rings. Several examples in the recent literature demonstrate advantage with this classical isosteric substitution.115,126-132 In the series of potent RSV fusion inhibitors captured in Table 24, the introduction of a pyridine ring was probed systematically with the objective of reducing the hydroxylation of the phenyl ring seen with the parent benzimidazol-2-one 115.114,115 Antiviral activity 2541 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry Table 24. Structure-Activity Relationships Associated with a Series of RSV Fusion Inhibitors was clearly sensitive to the topological location of the N atom, and preferred compounds demonstrated improved metabolic stability and increased solubility without introducing the burden of CYP 450 inhibition, a potential problem with pyridine derivatives. The 6-aza-benzimidazol-2-one discovered with 92 was ultimately incorporated into the clinical candidate that emerged from these studies.114,115 In a series of HIV-1 attachment inhibitors, the 4,7-dimethoxysubstituted indole 119 is a highly potent antiviral agent that is metabolized in HLM by O-demethylation, leading to the potential for quinone formation (120), a known toxicophore.126 A systematic survey that replaced CH with N at each of the aromatic sites of the indole ring revealed that the 6-aza analogue 121 (BMS-488043) offered improved aqueous solubility and abrogated the potential for reactive quinone formation should demethylation occur, which in this series would afford the amide 122.126 Compound 121 was advanced into clinical trials where it provided proof-of-concept for inhibition of HIV attachment as an approach to reducing HIV-1 replication in infected subjects.126 PERSPECTIVE also subject to oxidative bioactivation, a problem resolved by replacing the Cl atom with an electron withdrawing nitrile. In addition, the introduction of an O-methyl ether in the side chain successfully provided a metabolic soft spot to redirect metabolism, realizing 125 as a compound with an acceptable profile.127-129 3.3.2. N for CH in Phenyl Rings in Calcium Sensing Receptor Antagonists. In a series of short-acting calcium sensing receptor antagonists with potential for the treatment of osteoporosis, CYP 3A4-mediated oxidation of the phenol of 126 to the catechol 127 and then to the ortho quinone was identified as the source of GSH adducts in human and rat liver microsomes.130,131 The introduction of a nitrogen atom to the phenol ring (128) reduced the metabolic activation rate and markedly diminished the formation of GSH adducts by over 50-fold. This observation was supported by quantum chemistry calculations which indicated that oxidation of the aza-catechol derived from 128 to the quinone is energetically less favorable than for the benzene analogue 127. A similarly successful tactic has been described for the partially disclosed phenol ether chemotype 129 presented in Table 25 where tritiated derivatives were used to assess protein covalent binding (PCB) to human and rat liver microsomal proteins in the absence and presence of GSH.132 Iterative design optimization focused on the simple pyridine analogue 130, since 3,4-difluoro substitution of the phenyl ring of 129 3.3.1. N for CH in Phenyl Rings in CRF-1 Antagonists. The pyrazinone 123 is representative of a series of potent CRF-1 receptor antagonists, but 60% of the dose administered to rats appeared as oxidized metabolites in bile, with 25% of the dose excreted as GSH adducts.127-129 The phenyl ring was identified as the site of metabolic activation, producing the GSH adduct 124, which led to a focus on pyridine analogues. An initial survey indicated substantially reduced levels of bioactivation with the pyridine heterocycle series, and this element was ultimately incorporated into molecules selected for further development. However, the isolated olefin of the pyrazinone heterocycle was Table 25. In Vitro Protein Covalent Binding for the Phenol Ether 129 and Two Pyridine Analogues 2542 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 13. Calculated energies of syn and anti 2-methoxypyridine and 3-methoxypyridazine conformers. Figure 14. Conformational preference in 2-phenoxypyridines. reduced PCB by only 2-fold. Pyridine 130 exhibited 2- to 4-fold reduced PCB that was further refined by the introduction of a CF3 substituent to the heterocyclic ring to afford 131, which diminished microsomal protein binding to acceptable levels. In the example described above, the nitrogen atom replaces a carbon atom adjacent to the oxygen of an aryl ether to afford a 2-alkoxypyridine, an isosteric conversion that introduces implications with respect to conformational bias and which extends to other heterocyclic ring systems. As a consequence of the preferred orientation of in-plane lone pairs, the anti relationship between the lone pairs of the hetero atoms is strongly preferred based on calculated energies.91,133 This orientation is commonly observed in X-ray crystal structures, leading to an influence on substituent topology, an effect that extends to a range of nitrogencontaining heterocyles. 91,133 Figure 13 illustrates the calculated energetic preferences for 2-methoxypyridine and 3-methoxypyridazine.133 The design of a series of factor Xa inhibitors based on the 2,7-dibenzylidenecycloheptanone 132 took advantage of this phenomenon to productively influence conformation.134-136 The substituted phenoxy moiety in 133 was anticipated to act as a partial olefin isostere, presenting the aryl rings in a topology controlled by nonbonded interactions between the ether oxygen atom and pyridine nitrogen lone pairs. This concept is captured schematically in Figure 14, where syn and anti refer to the relationship between the lone pairs on the heteroatoms.134-136 These insights were incorporated into the design of ZK-807834 (134) in which the predicted topology of the amidine-substituted phenoxy moiety was observed in the X-ray of this compound complexed with factor Xa.136 Interestingly, however, the other phenoxy moiety adopted the alternative conformation reflected in the topology depicted in 134. 3.3.3. N for C Substitution in Dihydropyridine Derivatives. In a strategy seeking to interfere with metabolic deactivation of an active drug, a nitrogen-for-carbon switch was examined in a series of dihydropyridine (DHP)-based Ca2þ-channel blockers.137-140 Nifedipine (135) is a potent Ca2þ-channel blocker used as a coronary vasodilator that is subject to a facile first-pass oxidation in vivo to the inactive pyridine 136. The dihydropyrimidinone heterocycle was established as an effective isosteric pharmacophore that preserves the critical DHP NH as a H-bond donor based on the presence of either a carbonyl or thiocarbonyl at C-2. Acylation of the C-3 nitrogen (137) improved mimicry of the DHP ring system with ureido compounds 138 found to be more stable toward deacylation in vivo while favoring a topology analogous to that expressed in the DHPs based on dipole-dipole interactions and intramolecular H-bonding.137-140 Most importantly, the dihydropyrimidinone ring is resistant to oxidation, and this tactical application of bioisosterism was subsequently adopted to optimize a series of R1a-adrenergic antagonists based on a DHP core.141,142 3.4. Biphenyl and Phenyl Mimetics. 3.4.1. Biphenyl Mimetics in Factor Xa Inhibitors. In a series of potent factor Xa inhibitors related to razaxaban (139), the methoxyphenyl ring of 140 occupies the S1 pocket while the biphenyl moiety projects into the S4 pocket.143 Phenylcyclopropanes were explored 2543 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry as mimetics of the imidazole-phenyl and biphenyl elements of 139 and 140, respectively, in an effort to identify compounds with reduced molecular weight and a lower cLogP. With no benzylic (R-) substituent, the cyclopropane moiety of cyclopropylbenzene preferentially adopts a bisected conformation in which the C-H bond is coplanar with the phenyl ring, since this allows overlap of the cyclopropane orbitals with the π system.143 However, the introduction of a substituent at the Rposition favors the perpendicular conformation, preferred by 0.7 kcal/mol when the substituent is CH3. These insights led to the design of 141 in which the Me2N moiety is preferentially projected with a similar vector to that of the biphenyl, confirmed by an X-ray cocrystal of pyrrolidine 142 with factor Xa.143 Compounds 141 and 142 demonstrated markedly improved potency, a general phenomenon observed across several paired analogues that appears to be a function of optimized hydrophobic interactions with S4 and slightly reduced strain in the bound geometry. The cyclopropylmethyl moiety exhibits lower lipophilicity compared to the biphenyl 140, with both log P and clog P reduced by ∼1 log10.143 3.4.2. Phenyl Mimetics in Glutamate Analogues. S-4CPG (143) is a mGluR1 receptor antagonist in which activity is sensitive to both the distance between the CO2H and R-amino acid moieties and the linear topological relationship. The propellane 144 was explored as an isostere of the benzene ring in 143 and exhibited antagonist activity at mGluR1a.144-146 However, it was recognized that the distance between the CO2H functionalities in 144 is shorter than in 143, leading to the synthesis of the tetrazole 145 as a compound designed to address this deficiency. Although a logical design concept, this compound failed to demonstrate the anticipated improved antagonist potency at mGlur1a.146 The cubane analogue 146 was also prepared and found to be a modestly active antagonist of mGluR1b.145 PERSPECTIVE 3.4.3. Phenyl Mimetics in Oxytocin Antagonists. The poor aqueous solubility associated with a series of oxytocin antagonists represented by 147 precipitated a strategy designed to explore modification of the biaryl moiety, with a focus on saturated compounds that typically exhibit enhanced solubility.147,148 The azetidine (148), pyrrolidine (149), and piperidine (150) ethers were evaluated computationally and shown to exhibit good structural overlap with acceptable potency achieved experimentally with the azetidine 148. Optimization led to the identification of 151 in which the favorable cLogP of the prototype was maintained while aqueous solubility was improved by 10-fold.147 3.5. Phenol, Alcohol, and Thiol Isosteres. 3.5.1. Phenol and Catechol Isosteres. There has been a considerable investment in the identification of phenol and catechol isosteres in the medicinal chemistry literature, catalyzed largely by the development of agonists and antagonists of the biogenic amines adrenaline, dopamine, and serotonin, with the result that a range of useful surrogates are wellestablished, captured synoptically in Figure 15. The structural diversity, electronic properties, lipophilicity, and size of these functionalities varies widely, providing ample flexibility to customize for a 2544 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 15. Synopsis of phenol and catechol isosteres. specific application. These isosteres were typically designed to overcome pharmacokinetic and toxicological limitations associated with phenols, which can be glucuronidated as a prelude to excretion, while catechols are substrates for catechol O-methyl transferase (COMT). Phenols can also be hydroxylated at the ortho- or para-positions, affording catechols and 1,4-dihydroxybenzenes which can be further oxidized by CYP 450 enzymes to ortho- and paraquinones, chemically reactive metabolites with the potential to bind irreversibly to proteins, a possible source of toxicity. 3.5.2. Phenol Isosteres in Dopamine D1/D5 Antagonists. An interesting recent example that probed a series of phenol-containing dopamine dual D1/D5 antagonists highlights the need for careful analysis and consideration in the design and deployment of phenol isosteres.149 The phenol 152 (D1 Ki = 1.2 nM, D5 Ki = 2.0 nM) was advanced into clinical trials where it exhibited poor oral bioavailability due to first-pass metabolism (Figure 16). This prompted an examination of heterocycle mimetics designed to address the poor pharmacokinetic properties, with the recognition that this initiative also offered an opportunity to precisely map the topological vector associated with the phenolic H-bond donor based on the localization afforded by the complementary fused heterocyclic rings in 153 and 154 (Figure 16). Initial positive results with the indole 155 compared to the benzotriazole 156 indicated that the preferred topology of the H-bond donor is that in which the vector is projected parallel to the adjacent C-Cl bond, as depicted by 154 in Figure 16, rather than the alternative projection represented by 153.149 However, the benzimidazole 157 and benzotriazole 158 were found to be surprisingly poor mimetics despite projecting the H-bond along the appropriate vector. A closer analysis provided an explanation, with two observations germane to understanding the observed phenomenon: first, the azole heterocycles of both 157 and 158 can exist in two tautomeric forms, and second, the phenyl element of the tetrahydronaphthalene ring adopts a conformation in which it is orthogonal to the plane of the chlorophenyl ring. In the tautomeric form depicted by 158-A in Figure 17, the nitrogen lone pair and phenyl π cloud experience a repulsive interaction while in tautomer 158-B, the N-H and aryl π interact productively, engaging in π facial H-bonding. As a consequence, tautomer 158-B is more stable, providing a basis for the lower activity since the H atom is not available for interaction with the receptor. The relevance of tautomer 158-B was confirmed by analysis of the 1H NMR spectrum of the benzimidazole derivative where the NH was observed to resonate at δ 6.88, Figure 16. Considerations in the design of phenol mimetics in dual dopamine D1/D5 antagonists. Figure 17. Benztriazole tautomerism in dual dopamine D1/D5 antagonists. shielded by the π cloud, which compares with a δ 8.2 for the NH of benzimidazole. These insights predicted that the benzimidazol-2-one 159 and its thione analogue 160 with two H-bond donors should be active, a hypothesis confirmed experimentally. In the 1H NMR spectra of 159 and 160, the chemical shift of the NHs indicated that one was shielded by the aryl ring. The benzimidazol-2-one 159 is a highly potent D1/D5 dual ligand, and activity was preserved by the benzothiazolone analogue 161, with both chemotypes demonstrating improved PK properties in rats compared to the phenol progenitor 152.149 3.5.3. Alcohol and Thiol Mimetics 3.5.3.1. Sulfoximine Moiety As an Alcohol Isostere. Sulfoximines are the aza analogues of sulfones, and the introduction of the mildly basic nitrogen atom (pKa of the protonated form is 2.7) creates asymmetry at sulfur, with the enantiomers 2545 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 18. Physical properties of the sulfoximine moiety. readily resolved and configurationally stable, fundamental properties summarized in Figure 18.150 Although isosteric with sulfones, sulfoximines offer an additional substituent vector capable of projecting a range of functionality. N-Unsubstituted sulfoximines are also capable of being phosphorylated in vivo, biochemical pharmacology that was instrumental in the original discovery of the sulfoximine functionality in methionine sulfoximine, a proconvulsant produced in a chemical process used to bleach flour.151 Phosphorylation of methionine sulfoximine afforded a mimetic of glutamate that inhibited both glutamine and γ-glutamylcysteine synthetases, the former leading to increased levels of glutamate in the brain, the ultimate cause of the observed convulsions.151 The unique properties of sulfoximines periodically attract the attention of medicinal chemists, and applications of this functionality have been examined in a variety of settings.150,152 On the basis of its tetrahedral topography, H-bond accepting properties, and the acidity of the NH, pKa = 24, which compares favorably with that of an alcohol (pKa of MeOH is 29; pKa of i-PrOH is 30.2; pKa of t-BuOH is 33; all measured in DMSO), the sulfoximine moiety has been explored with some success as an alcohol isostere in inhibitors of HIV-1 protease.153-155 However, an attempt to extend the sulfoximine-alcohol bioisosterism to the HIV-1 protease inhibitor indinavir (166) by preparing the sulfoximine analogue 167 revealed surprisingly poor inhibitory activity with an IC50 that was determined to be 250000-fold higher than that of the alcohol 166.155 Although no structural data were obtained, docking studies suggested that the result may be a function of the limited conformational flexibility associated with this particular peptidic template that interferes with the ability of 167 to adopt an optimal binding orientation. 3.5.3.2. RCHF2 as an Isostere of ROH. The difluoromethyl ethers CF3OCHF2 and CHF2OCHF2 have been shown to donate a H-bond to a variety of bases, while the CHF2 moiety engages in intramolecular H-bonding with a proximal carbonyl moiety, studied in the context of the pyrazole fungicide 168 for which the CF3 analogue exhibited weaker biological activity.156 Both the IR and 1H NMR spectral data for 168 were consistent with an intramolecular H-bond estimated to be about 1.0 kcal/mol, a weak H-bond donor compared to more traditional interactions which typically range from 2 to 15 kcal/mol. However, the CF2H is a more lipophilic H-bond donor than either OH or NH, offering the potential for improved membrane permeability.157 The racemic sulfoximine analogue 163 of the potent HIV-1 protease inhibitor L-700417 (162) was synthesized and shown to be only 4-fold less potent than the progenitor in vitro and active as an antiviral in cell culture, EC50 = 408 nM, without overt cytotoxicity, CC50 > 10 μM.153,154 The sulfoxide 164 also demonstrated biological activity, IC50 = 21.1 nM, but the sulfone 165 was poorly active, suggestive of a role for the sulfoximine NH in alcohol mimicry. 3.5.3.3. RCHF2 as a Thiol Mimetic in HCV NS3 Protease Inhibitors. Although the CF2H moiety has not been widely exploited by medicinal chemists, it is beginning to attract attention and several interesting applications have recently been examined. In one of the most successful demonstrations of utility, the RCHF2 moiety was recognized as a potential isostere of a thiol in the context of inhibitors of HCV NS3 protease, an important antiviral target that cleaves substrates at the carboxy terminal of cysteine. Difluoro-Abu was designed as a potential isostere of the cysteine CH2SH P1 element in peptide-based inhibitors following a careful analysis of properties that indicated substantial structural similarity.158 The van der Waals surfaces of the two elements are similar (HCF2CH3, 46.7 Å; HSCH3, 47.1 Å), while electrostatic potential maps indicated surface similarities between the negative potential around the sulfur lone pairs and the two fluorine atoms and the positive potential around the CF2 H and SH hydrogen atoms, captured in a simplistic fashion in Figure 19. The difluoro-Abu analogue 171 of the hexapeptide NS3 inhibitor 169 proved to be equipotent and 20-fold more potent than the simple Abu derivative 170. An X-ray cocrystal of a related inhibitor revealed the key ligand-protein interactions, 2546 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE reaction pathways summarized in Figure 20.162 Metabolism and toxicity are dependent on structure, and several hydroxamic acidcontaining drugs have successfully reached the market, the most recent being the HDAC inhibitor vorinostat (175) launched in 2006 as a treatment for cutaneous T-cell lymphoma (CTCL).163 Figure 19. Similarity of the electronic and steric properties of cysteine and difluoro-Abu. Figure 20. Metabolic pathways associated with hydroxamic acids. with the CF2H moiety donating a H bond to the CdO of Lys136 and one fluorine close to the C-4-hydrogen atom of Phe154, suggestive of a weak C-H to F hydrogen-bond.158 3.5.3.4. Application of RCHF2 as an Alcohol Isostere in Lysophosphatidic Acid. Lysophosphatidic acid (172, LPA) interacts with G-protein-coupled receptors (GPCRs) that have been classified into four subtypes, designated LPA1-4, and also acts as an agonist for the nuclear hormone receptor PPARγ. Acting on its cognate GPCRs, compound 172 mediates cell proliferation, migration, and survival, providing an opportunity for antagonists to exhibit potential utility in oncological applications. The CF2Hcontaining analogues diF-LPA (173) and its homologue 174, were designed as isosteres of 172 in which troublesome migration of the acyl moiety is prevented.159,160 Compound 173 was found to stimulate luciferase production in CV-1 cells transfected with luciferase under control of a PPARγ-responsive element. However, neither 173 nor 174 interacted appreciably with LPA receptors 1-3, either as agonists or antagonists, providing an interesting example of an isostere enhancing specificity.159 The potential of a CHF2 moiety to act as an isostere of the hydroxyl of hydroxamic acids has been evaluated in a series of dual inhibitors of cycloxygenase-2 (COX-2) and 5-lipoxygenase (5-LOX), molecules designed to prevent arachidonic acid metabolism being directed to the alternative pathway by single enzyme inhibition as a means of reducing the potential for side effects.164 Hydroxamic acids are well-established inhibitors of 5-LOX, binding to the active site iron, and substitution of the toluene ring of 16 with a cyclic hydroxamic acid affords the dual inhibitor 176 (Table 26). The NCHF2 analogue 177 was explored as a non-hydroxamic acid isostere and appeared to be an effective mimetic, although the mechanism of action of this compound has not been fully clarified. Nevertheless, 177 shows protective activity in the rat carrageenan foot paw edema model following oral administration.164 In the alternative series of alkyne-based cyclooxygenase inhibitors 178-180 where the cyclic hydroxamic acid effectively introduced 5-LOX inhibition (Table 27), a difluoromethylpyridone isostere provided consistent 5-LOX inhibition across the series of analogues 181-184 (Table 28).165 These compounds appear to offer improved activity in the carrageenan-induced rat paw edema model of inflammation following oral dosing, with activity in vivo attributed to 5-LOX rather than COX inhibition because of the weaker in vitro COX-1 and COX-2 inhibitory activity associated with these compounds.165 This hydroxamic acid isostere has subsequently been explored as a means of introducing LOX inhibition to a range of cyclooxygenase-inhibiting chemotypes.166-170 Table 26. Cyclooxygenase and Lipoxygenase Inhibition Associated with a Series of Pyrazole-Based Inhibitors Table 27. 5-Lipoxygenase Inhibition by a Series of Alkyne-Based Hydroxamic Acid Derivatives 3.6. Hydroxamic Acid Isosteres. 3.6.1. Application of RCHF2 to Hydroxamic Acid Isosteres. Hydroxamic acids are excellent ligands for metals, particularly zinc, and are a key pharmacophoric element for both matrix metalloprotease and histone deacetylase (HDAC) inhibitors.161 However, hydroxamic acids can express toxicity based on metabolic activation, which manifests either as a Lossen rearrangement to the corresponding isocyanate or as hydrolytic degradation to release a carboxylic acid and hydroxylamine, with the latter a cause of methemoglobinemia, 2547 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 28. Cyclooxygenase and 5-Lipoxygenase Inhibition by a Series of Alkyne-Based N-Difluoromethylpyridone Derivatives Figure 22. Hydroxamic acid motifs explored as the key Zn2þ-binding pharmacophore in metalloprotease inhibitors. Figure 23. Isosteres of the hydroxamic acid moiety explored in the context of tumor necrosis factor-R-converting enzyme (TACE) inhibitors. Figure 21. Binding of substrate (A) and the inhibitor 186 (B) to carbonic anhydrase II. 3.6.2. Hydroxamic Acids in Carbonic Anhydrase II Inhibitors. In a somewhat unusual example of intrinsic bioisosterism that relies upon the potential for ambidentate binding modes, the hydroxamic acid derivatives 185 and 186 were found to bind in an unanticipated fashion to carbonic anhydrase II, a 260 amino acid enzyme in which a Zn2þ atom catalyzes the addition of H2O to CO2 (Figure 21A).171 In this enzyme, Thr199 accepts a H-bond from Zn2þ-bound hydroxide and donates to Glu106 as part of the catalytic mechanism and simple hydroxamic acids were probed as inhibitors based on the known propensity of this functionality to bind to Zn2þ via a five-membered chelate involving the two oxygen atoms. Both compounds inhibit enzyme function with IC50s in the micromolar range, but an X-ray cocrystal revealed that both inhibitors bound in a similarly unusual mode in which the nitrogen atom is ionized and coordinates to the Zn2þ, a binding orientation stabilized by a H-bond donated from Thr199 to the hydroxamate carbonyl (Figure 21B). In the case of 186, an additional, weakly polar C-FfZn2þ appears to add to the stability of the complex.171 3.6.3. Hydroxamic Acid Mimetics in TNFR-Converting Enzyme (TACE) Inhibitors. The bidentate interaction of hydroxamic acids with the metal of Zn2þ metalloproteases offers increased potency compared to monodentate ligands like the thiol found in captopril or the carboxylic acid of lisinopril, both potent ACE inhibitors. However, hydroxamic acids typically bind more tightly to Fe(III) and often exhibit poor pharmacokinetic properties due, in part, to hydrolytic cleavage of the hydroxamate and release of NH2OH, although the alternative hydroxamic acid structures presented in Figure 22 may abrogate this pathway. These limitations have stimulated the identification of useful hydroxamic acid surrogates with improved properties, with the more common isosteres probed in the context of tumor necrosis factor-R-converting enzyme (TACE) inhibitors summarized in Figure 23. Unlike hydroxamic acids, which bind as depicted in Figure 24A, many of these isosteres are thought to coordinate Zn2þ in a monodentate fashion that requires additional enzyme-inhibitor interactions for optimal potency and selectivity (Figure 24, B and C).161,172 Imides were proposed to enolize and displace the nucleophilic H2O that is activated by Glu406, providing an explanation for the pKa of 7-9 that is required for these chemotypes to be effective inhibitors.161,172 An X-ray cocrystallographic analysis of a structurally simple hydantoin-based TACE inhibitor has recently elucidated the binding mode in the enzyme active site, confirming the monodentate interaction with Zn2þ in the S1 subsite but also revealing the presence of a second molecule in the S10 subsite.173 3.7. Carboxylic Acid Isosteres. Isosteres of carboxylic acid have been studied extensively, driven in part by interest in inhibitors of the arachidonic acid pathway and excitatory amino acids receptors and by the development of angiontensin II receptor antagonists. These studies have typically focused on enhancing potency, reducing polarity, and increasing lipophilicity in order to improve membrane permeability, enhancing pharmacokinetic properties in vivo and reducing the potential for toxicity. The latter is based on the potentially problematic rearrangement of acyl glucuronides formed in vivo that can lead to chemically reactive species, while CoA esters, another potential metabolite, are electrophilic and have been implicated as a source of toxicity.174 A synopsis of the more common carboxylic acid isosteres is presented in Figure 25. The use of heterocycles, either those with intrinsic acidity or those in which substituents are used to modulate pKa, not only broadens the palette of carboxylic acid isosteres but offers considerable additional structural variation with which to enhance complementarity to a target protein or nucleic acid. A synopsis of acidic heterocycles that have been explored as acid isosteres is provided in Figure 26 where patterns of substitution and the potential for charge delocalization by enolization offer additional flexibility to modulate vectorial projection and reach while providing for a wide-ranging structural diversity. 3.7.1. Carboxylic Acid Isosteres in Angiotensin II Receptor Antagonists. Angiotensin II receptor antagonists provide 2548 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 24. Proposed binding mode of hydroxamic acid and nonhydroxamic acid tumor necrosis factor-R-converting enzyme (TACE) inhibitors. Figure 25. Synopsis of the more common carboxylic acid isosteres. Figure 26. Synopsis of heterocycle-based carboxylic acid isosteres. instructive insight into carboxylic acid isostere design, since binding affinity to the receptor in a series of biphenyl acids is quite sensitive to the identity of the acidic element.175,176 The tetrazole moiety in losartan (188) confers a 10-fold increase in potency compared to the carboxylic acid analogue 187, a result explored through geometrical analysis that indicated that the tetrazole projects the acidic NH 1.5 Å further from the aryl ring than a CO2H (data summarized in Figure 27). The CON- HSO2Ph moiety incorporated into 189 exhibits a similar geometrical topology to CO2H and offers comparable potency. However, the reverse acylsulfonamide, SO2NHCOPh, found in 190 with its longer aryl ring-S bond length projects the charge further away from the biphenyl core, more effectively approximating the Ar to distal NH distance in the more potent tetrazole, particularly if the negative charge resides on the carbonyl oxygen, as might be anticipated.175,176 2549 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 29. Structure-Activity Relationships Associated with the Acylsulfonamide Moiety of a Series of Tripeptidic Inhibitors of HCV NS3 Protease Figure 27. Geometrical arrangements associated with the carboxylic acid moiety and tetrazole and acysulfonamide isosteres in angiotensin II antagonists. In a second example from the angiotensin antagonist field, L-158809 (191) was identified as a potent and selective AT1 antagonist, IC50 = 0.3 nM, that shows prolonged antihypertensive activity in rats that lasted for more than 6 h after iv or po dosing.177 However, the duration was shorter in dog and rhesus monkey following iv dosing, attributed to rapid clearance by glucuronidation of the tetrazole moiety. Replacing the tetrazole of 191 with an acylsulfonamide, as exemplified by 192, preserved potency (IC50 = 0.2 nM) and extended the hypotensive effect in rats to over 6 h following po dosing. A similarly long duration of action was observed in the dog and rhesus monkey, results attributed to the resistance of the acylsulfonamide toward glucuronidation.177 3.7.2. Acylsulfonamide in HCV NS3 Protease Inhibitors. The potency of the tripeptidic acid-based inhibitor of HCV NS3 protease 193 can be improved by occupying the well-defined P10 pocket that is ignored by the carboxylate.178 The P10 pocket is readily and uniquely accessed by an acylsulfonamide moiety that preserves acidity while establishing H-bonding interactions between the protease active site and both oxygen atoms of the sulfone (Table 29).178 A cyclopropylacylsulfonamide (194) is optimal based on comparison with the homologues 195-197 and typically confers a significant potency advantage to the extent that this moiety has been widely adopted by the industry.179 3.7.3. Acylsulfonamide in EP3 Antagonists. The potent carboxylic acid-based EP3 antagonist 198 shows modest functional activity in blocking PGE2-induced Ca2þ release in cells in culture, but modification to the N-phenylacylsulfonamide 200 afforded a compound with 40-fold increased binding affinity, attributed to the contribution of productive interactions between the larger inhibitor and the receptor (Table 30).180 However, functional activity remained poor, considered to be due to high compound binding to the 1% BSA protein present in the medium. Substitution of the phenyl ring improved potency and efficacy, with the 3,4difluoro analogue 201 being 256- and 480-fold more potent in the binding and functional assays, respectively.180 3.7.4. Acylsulfonamides in Bcl-2 Inhibitors. An acylsulfonamide moiety proved to be a critical element in a series of inhibitors of Table 30. Structure-Activity Relationships Associated with a Series of EP3 Antagonists the antiapoptotic protein Bcl-2 that have application in oncology therapy. NMR screening (SAR by NMR) identified two structural fragments, the biphenylcarboxylic acid 203 and the phenol 204, that bound weakly to Bcl-2, confirmed using a fluorescence polarization assay (FPA) (Figure 28).181,182 However, attempts to link the 2 fragments via the ortho position of the benzoic acid fragment, as depicted by 205, failed to identify molecules with increased binding affinity. The acylsulfonamide 206 provided a more effective vector to access the Ile85 pocket occupied by the phenol 204 while preserving the acidic functionality that interacts with Arg139 of the Bcl-2 protein.181,182 ABT263 (207) ultimately emerged from this work as a clinical candidate that is orally bioavailable despite a molecular weight of 974. Acylsulfonamides and several other carboxylic acid isosteres developed originally for medicinal chemistry applications have found utility in proline-based organocatalyst design as a means of modulating physical properties to overcome limitations associated with proline.183,184 3.7.5. 2,6-Difluorophenol as a CO2H Mimetic. The introduction of fluorine atoms at the 2- and 6-positions of phenol increases the acidity from a pKa of 9.81 for phenol to a pKa of 7.12 for 2,6difluorophenol, prompting the hypothesis that this functionality may function as a lipophilic carboxylic acid mimetic.185 The concept of an isosteric relationship was based on a combination of the acidity of the 2550 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE useful isosteres of carboxylic acids and tetrazoles in the context of angiotensin II antagonists based on their high intrinsic acidity; the pKa of 3-hydroxy-4-phenylcyclobut-3-ene-1,2-dione (212), for example, is 0.37.188 Figure 28. Fragments binding to Bcl-2 identified by NMR studies. OH and the potential for fluorine to mimic the carboxylic acid CdO by acting as a H-bond acceptor. With a view to improving the poor CNS penetration of 25, the more lipophilic186 2,6-difluorophenol derivatives 208 and 209 were synthesized and found to be competitive inhibitors of GABA amino transferase, although neither acted as a substrate.185 The 2,6-difluorophenol moiety was also examined as an isostere of the carboxylic acid in the aldose reductase inhibitor 210 with the result that 211 offered 6-fold increased potency.187 The affinity of the squaric acid derivative 213 for the angiotensin II receptor was within 10-fold of that measured for the tetrazole 214 and superior to both the carboxylic acid 215 and sulfonamide 216.175,188 This was attributed to the increased size of the cyclobutenedione moiety and its ability to project acidic functionality an optimal distance from the biphenyl core (Table 31).175,188 Squarate 213 reduced blood pressure in Goldblatt hypertensive rats following oral administration with a long lasting effect, although efficacy was lower than the analogous tetrazole.188 3.7.7. Aminosquarate Derivatives as Amino Acid Mimetics. In an elegant example of isostere design, diaminosquaric acid derivatives 218 were conceived as achiral mimetics of glutamic acid (217) based on structural homology, the inherent strong dipole, and electron density residing on the oxygen atoms that is supported by the NH moieties, depicted by the tautomers in Figure 29.189 Several of these molecules, in which the amine is nonnucleophilic and neither basic nor acidic at neutral pH, exhibited modest affinity for the N-methy-D-aspartate (NMDA) glutamate receptor but showed no activity at R-amino-3-hydroxy-5-methyl4-isoxazolepropionic acid (AMPA) or kainate receptors (data summarized in Table 32). The phosphonate derivative was a somewhat more potent NMDA ligand, although all showed markedly lower affinity than glutamic acid, IC50 = 70 nM.189 3.7.8. Heterocycles as Amino Acid Mimetics. Amino acid isosterism that exhibits some analogy to the amino squarate chemotype has been recognized in the series of heterocycles summarized in Figure 30, explored as antagonists of the AMPA receptor subtype that recognizes glutamate and the glycine site associated with the NMDA receptor. For the quinoxaline diones, effective mimicry of glycine is thought to rely on the tautomeric isomerism highlighted in the bolded enol form depicted in Figure 30 that overlays the corresponding elements of glycine with good toplogical similarity.190 Isosterism with AMPA was Table 31. Structure-Activity Relationships Associated with Isosteres of a Carboxylic Acid in a Series of Angiotensin II Receptor Antagonists 3.7.6. Squaric Acid Derivatives as CO2H Mimetics. Cyclobutenediones, more commonly referred to as squaric acids, are 2551 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 29. Structures of glutamic acid, a diaminosquaric acid derivative, and its tautomers. Table 32. Binding Affinity for a Series of Diaminosquaric Acid-Based NMDA Antagonists Figure 30. Synopsis of heterocycle-based isosteres of glycine and R-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA). established by incorporating an additional acidic moiety, although the enol form of the quinoxaoline dione appears to be of lesser importance in this context.190 Potency and selectivity can be further modulated by varying the nature and pattern of substitution of the heterocycle N atom and the fused benzene ring that allows control of vector presentation. 3.8. Isosteres of Heterocycles. 3.8.1. Avoiding Quinonediimine Formation in Bradykinin B1 Antagonists. The 2,3-diaminopyridine 219 is a potent bradykinin B1 antagonist, Ki = 11.8 nM, that was being evaluated as a potential treatment for the relief of pain (Figure 31).191 However, the diaminopyridine moiety is susceptible to metabolic activation by both rat and human liver microsomes, forming glutathione (GSH) adducts 221 that were observed in rat bile following oral administration of 219.191,192 The metabolic activation pathway was considered to be via formation of either the diiminoquinone 220 or the generation of a pyridine epoxide 222, both of which are anticipated to be electrophilic toward GSH, with the latter specifically producing 224, as summarized in Figure 31. Oxidation of 219 to the Noxide 225 was also observed, although GSH addition to this metabolite appeared to be a minor pathway.191,192 The design strategy to identify a suitable replacement for the 2,3-diaminopyridine scaffold of 219 relied upon the premise that both NHs were important, allowing simplification to an ethylene diamine 226 as the fundamental linker element, as depicted in Figure 32.193 An acyl moiety was introduced in a fashion that allowed the CdO element to mimic the pyridine nitrogen atom while simultaneously acidifying the pendent NH, thereby modifying the linker to that of an R-amino acid 227. In order to favor the topology of the substituents presented by the pyridine scaffold, the final design consideration sought to exploit the Thorpe-Ingold effect194 represented generically by 228. However, the dimethylglycine analogue 229 exhibited only modest affinity for the B1 receptor but potency was improved substantially by optimization to the cyclopropyl analogue 230. This result was attributed to the effect of π-π hyperconjugation between the cyclopropyl C-C bonds and the amide CdO exerting a conformational bias based on the in- Figure 31. Metabolic pathways associated with the bradykinin B1 receptor antagonist 219. Figure 32. Principles underlying the design of a 2,3-diaminopyridine isostere in the context of the bradykinin B1 receptor antagonist 219. creased π character of cyclopropyl C-C bonds which can optimally interact with the amide CdO moiety at 0° and 180° (summarized in Figure 33). Moreover, the 116° bond angle enforced by the cyclopropyl ring is closer to the 120° vector inherent to the pyridine 2552 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 34. Equilibrium of complex formation used to establish hydrogen bonding potential pKBHX of acceptors. Figure 33. Conformation and topology of cyclopropyl amino acid amides as 2,3-diaminopyridine mimetics. Table 33. pKBHX Values for Common Functional Groups Arranged in Order of Descending Hydrogen-Bond Basicity functionality core (Figure 33). This isostere was also applied with some success to the factor Xa inhibitor 231, with 232 showing only a 4-fold loss in potency.193 3.8.2. Isosterism between Heterocycles in Drug Design. Five- and six-membered heterocycles play a prominent role in drug design, ubiquitous in their application as drug scaffolds or important structural elements. The versatility of heterocycles is based on their size and shape, which allows substituent projection along a range of vectors, while inherent electronic and physical properties are of importance in mediating drug-target interactions. By judicious selection and deployment of substituents, electronic and physical properties and acidity and basicity can readily be modulated in an incrementally graded fashion, particularly for unsaturated heterocycles. The most important properties in drug design and biofunctional mimicry are H-bond donor (N-H, O-H, C-H) or acceptor properties, electron withdrawing or donating effects, and the potential to engage in π-π interactions. In addition, tautomerism offers additional opportunities to optimize both the topographical presentation of substituents and drug-target interactions while heterocycles incorporating a bivalent sulfur atom provide unique opportunities for inter- and intramolecular interactions that have demonstrated relevance in drug design. Although the silhouettes of unsaturated heterocyclic rings within a homologous five- or six-membered series are similar, their inherent physical and electronic properties frequently lead to significant discrimination of their capacity to function as isosteres of each other in biological systems. There are many situations where the careful selection of a heterocycle has been a critical element in successfully addressing a specific problem encountered in drug design or introducing targeted activity. Consequently, a detailed understanding of the fundamental properties of individual heterocycles is Me3PdO pKBHX 3.53 pyrrolidine 2.59 MeSO.Me 2.54 (Me)2NCON(Me)2 2.44 N-Me-pyrrolidone 2.38 n-PrCO.N(Me)2 2.36 Et2NH 2.25 N-Me-pyrrolidine EtNH2 2.19 2.17 Me2NCHO 2.10 Et3N 1.98 morpholine 1.78 c-C3H5NH2 1.72 δ-valerolactone 1.57 cyclohexanone 1.39 oxetane MeSO2N(Me)2 1.36 1.30 THF 1.28 acetone 1.18 MeSO2Me 1.10 EtOAc 1.07 EtOH 1.02 EtOEt 1.01 CH3CN 0.91 of paramount importance if they are to be deployed effectively in a fashion that takes advantage of properties that can be uniquely dependent on context. 3.8.3. Heterocycles as Hydrogen Bond Acceptors: pKBHX Scale of H-Bonding Basicity. The pKBHX (previously pKBH) scale of hydrogen bond basicity has been developed based on the formation of a complex between the acceptor and 4-FC6H4OH in CCl4 at 298 K, monitored by Fourier transform infrared techniques as a shift in the frequency of the OH stretching vibration.195-198 In this experiment, a strong H-bond acceptor forms a complex with 4-FC6H4OH that exhibits a large association constant (K) and low dissociation constant (1/K), the position of equilibrium defining the strength of the H-bond (Figure 34). Thus, a strong acceptor has a higher pKBHX. H-Bonding strength has been found to depend on multiple factors including the position of the acceptor atom in the periodic table, polarizability, field/ inductive and resonance effects of substituents around the acceptor atom, proximity effects, steric hindrance surrounding 2553 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 34. Comparison of pKBHX and pKBHþ (pKa) Values for Common Five- and Six-Membered Ring Heterocycles heterocycle pKBHX pKBHþ (pKa) 1-methylimidazole 2.72 7.12 imidazole 1-methylpyrazole 2.42 1.84 6.95 2.06 thiazole 1.37 2.52 oxazole 1.30 0.8 isoxazole 0.81 1.3 furan -0.40 pyridazine 1.65 2.00 pyridine 1.86 5.20 pyrimidine pyrazine 1.07 0.92 0.93 0.37 triazine 0.88 the acceptor site, the potential for intramolecular H-bonding, and lone pair-lone pair interactions.195-198 3.8.4. H-Bonding Capacity of Common Functional Groups. The pKBHX scale provides an excellent index of H-bonding basicity, and experimentally determined data are available for many of the functional groups commonly encountered in medicinal chemistry. As summarized in Table 33, the H-bonding capacity of esters, ethers, and ketones falls in the range of pKBHX = 1.00-1.50 while amides, carbamates, and ureas act as stronger acceptors, pKBHX ≈ 2.00-2.55.196 Sulfoxides are good H-bond acceptors, pKBHX = 1.70-2.50, with sulfones and sulfonamides somewhat weaker, with pKBHX values ranging from 1.10 to 1.40. Although these functional groups present a good dynamic range and are commonly deployed in drug design, they frequently offer only limited potential for subtle and graded optimization of electronic properties or modulation of vector projection topology that is frequently of importance in the optimization of drug-target interactions. In addition, many of these functional groups can present problems based on pharmacokinetic or toxicological considerations. Heterocycles offer several advantages in this context, providing a broad range of H-bond acceptor properties and often improved metabolic stability compared to, for example, esters, amides, ketones, and aldehydes.196-198 3.8.5. Heterocycles and H-Bonds: Filling the Gaps. The H-bond-accepting capacity of a series of simple five- and sixmembered heterocycles that are widely used in drug design is compiled in Table 34 along with proton basicity measurements pKBHþ. These data demonstrate the potential of heterocycles to offer graded variation in H-bonding capacity, and this property can be refined further in a subtly graded fashion by the careful selection and deployment of substituents. Moreover, selection between heterocycles facilitates optimization of shape, size, and vector presentation to effectively complement a specific drug target.196-198 3.8.6. H-Bonding and Brønsted Basicity Differences. It is important to recognize that the Brønsted proton basicity (pKBHþ) and H-bonding basicity, as determined by pKBHX measurement for acceptors, shows a poor quantitative correlation across functional groups, although correlations do typically exist within homologous series (Table 34).196 As an illustrative example, the pyrrolidine N atoms of nicotine (233) and nornicotine (234) are the first sites of protonation in water but 90% of the H-bonding Figure 35. H-bonding associated with the pyridazine heterocycle. interaction between 4-fluorophenol and 233 occurs at the pyridine nitrogen while for 234 the figure is 80%.199 This observation has been attributed to the electron withdrawing and steric effects associated with the pyridine ring interfering with access to the pyrrolidiine nitrogen atom. Cotinine (235) is also a bifunctional H-bond acceptor, and in this case the amide carbonyl has been determined to be the major site of H-bonding in all solvents.199-205 The H-bond basicity of the amide moiety of 235 is 1.6 units higher than that of the pyridine nitrogen atom despite the fact that pyridine, with pKBHþ = 5.20, is more basic than the amide carbonyl, pKBHþ = -0.71. Similarly, N,N-diethylnicotinamide (236) protonates on the pyridine nitrogen atom but the amide is a markedly stronger H-bond acceptor.199-205 Within the homologous series of six-membered heterocycles, pyridazine is an outlier from the correlation between Brønsted basicity (pKBHþ) and pKBHX, providing an interesting exception that can be exploited in drug design (Table 34). The H-bond acceptor properties of pyridazine approaches those of pyridine, but it is much less basic while it is both a better H-bond acceptor and more basic than pyrazine and pyrimidine.196,197,206 The higher than expected H-bond accepting strength of pyridazine has been attributed to the R-effect which reflects unfavorable electrostatic lone pair-lone pair interactions that are relieved by accepting a H-bond from a donor (Figure 35). Interestingly, pyridazines do not appear to be overtly associated with CYP P450 inhibition, suggesting that this ring system may be a useful isostere in situations where H-bonding is important but pyridine may cause problems. As an illustrative example, the mechanismbased fatty acid amide hydrolase (FAAH) inhibitor 237 inhibited CYP 2D6 with an IC50 of 1.4 μM and CYP 3A4 with an IC50 of 0.8-4.3 μM depending on the substrate.207 However, the pyridazine analogue 238 exhibited a 2-fold improvement in FAAH inactivation kinetics that was associated with a 10-fold reduction in CYP 2D6 inhibiton while CYP 3A4 was weakly inhibited, IC50 of 30 μM, regardless of the substrate used.207 3.8.7. Pyridazine H-Bonding in p38R MAP Kinase Inhibitors. A series of p38R mitogen-activated protein (MAP) kinase inhibitors that bind to the ATP site of the enzyme provides an interesting illustration of the unique H-bond accepting properties of the pyridazine heterocycle.208 The phthalazine 239 resulted from careful optimization as a potent p38 MAP kinase 2554 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 38. Interactions between the imidazole-based p38R MAP kinase inhibitor 244 and the enzyme and the structure of two analogous inhibitors 245 and 246. Figure 36. Key binding interactions between the p38R MAP kinase inhibitor 239 and the enzyme and the structure of an optimized analogue 240. Figure 39. Electrostatic potential of heterocycles designed to interact with Met109 in the hinge region of p38R MAP kinase. Figure 37. Topology of H-bonding interactions between 2-methylaminopyridine and a phenol. Table 35. H-Bonding Basicity (pKBHX) Associated with Derivatives of 2-Aminopyridine inhibitor, IC50 = 0.8 nM, with excellent selectivity over the related enzymes Kdr, Lck, CKit, JNK1, JNK2, and JNK3. An X-ray cocrystal of 239 with p38R kinase revealed that the pyridazine element established H-bonds with the NHs of both Met109 and Gly110, with the latter flipping to project its amide hydrogen into the ATP bonding pocket, a conformational change that accounted for the high enzyme specificity (Figure 36).208 This phthalazine chemotype formed the basis for further optimization focused on improving pharmacokinetic properties with the pyrido[2,3-d]pyridazine derivative 240, a refined compound that reduced paw swelling in a rat collagen-induced model of arthritis.209,210 3.8.8. Heterocycle Substituents and H-Bonding. 2-Dimethylaminopyridine (241) exhibits reduced H-bond basicity compared to 2-methylaminopyridine (242) and 2-aminopyridine (243) (data compiled in Table 35).211 This effect is not considered to be steric in origin based on analogy to 2-picoline and 2-isopropylpyridine where there is only a 0.27 difference in pKBHX. Rather, this observation has been attributed to an artifact of the method of measuring H-bonding potential. In this case, an additional H-bond forms between the NH and the oxygen atom of the phenol used to assess H-bonding in 242 and 243 that is unavailable to 241, as summarized in Figure 37.211 3.8.9. Heterocycle Isosteres in p38R MAP Kinase Inhibitors. The H-bond between the NH of Met109 in the hinge region of p38R MAP kinase and inhibitors is a critical drug-target interaction in a series of 4,5-disubstituted imidazole derivatives that were established as effective inhibitors, exemplified by SB-203580 (244) (Figure 38).212,213 In smaller inhibitors, the benzimidazol-2-one 246 was established as an effective isostere for the pyridine, a source of CYP 450 inhibition, in 245 since both compounds inhibited p38R MAP kinase with similar potencies. However, an attempt to replace the pyridine of 244 with a benzimidazol-2-one was not successful, attributed to the larger heterocycle altering the bound conformation such that the introduction of an aryl substituent at C-2 of the imidazole ring projected this moiety beyond the boundaries of the ATP binding site. As a consequence, potency was decreased by over 40-fold and smaller H-bond acceptors to replace the benzimidazol-2-one moiety were sought. Compound design focused on benzo-fused, diheteroatomic systems, since saturated single heteroatom systems would possess hydrogen atoms or lone pairs projecting orthogonally 2555 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 40. Examples of functionality with two potential H-bond acceptors. Figure 42. Energetics (kJ/mol) of the interaction of H2O with O atoms in common functional groups. Figure 41. Comparison of the calculated energetics (kJ/mol) of the interaction of H2O with N and O atoms in molecules incorporating both elements. to the ring plane. Molecular electrostatic potential maps were generated for the series of truncated heterocycles captured in Figure 39 which revealed that the benzimidazol-2-one moiety was closest to pyridine, but hydrophobicity, π-π stacking interactions, and dipoles were also considered in the analysis.212,213 However, the predictions were associated with sufficient ambiguity to necessitate experimental evaluation and an X-ray cocrystal of the triazolopyridine 250 revealed two H-bonding interactions between the kinase and the inhibitor, one from Met109 NH to N3 and a second from Gly110 NH to N2. However, the benzo-1,2,3-triazole derivative 248 was 5-fold more potent in the context of 251, an observation attributed to hydrophobic and π-π interactions in addition to desolvation effects. The free energy of binding divided by the number of heavy atoms, a measure of ligand efficiency, indicated that the benzimidazol-2one moiety was the least efficient of these ligands.212,213 3.8.10. Heteroatoms as H-Bond Acceptors. Two approaches have been taken to address the question of which atom, O or N, engages a H-bond donor in a competitive situation where both are available as acceptors as in, for example, alkoxypyridines, alkoximes, oxazoles, and isoxazoles (Figure 40). An ab initio study of functional groups complexed with water provided theoretical insight, while an analysis of H-bonding interactions in molecules presenting both opportunities in the CSD catalogued practical examples.214 Table 36. Statistics Associated with the Presence and Number of H-Bonds to N and O in Functional Groups in the Cambridge Structural Database214 no. of fragments no. H bonds to N no. H bonds to O oxazole 36 17 isoxazole 75 25 0 3-MeO-pyridine 12 7 0 136 4 0 oxime ether 1 The ab initio studies calculated H-bond lengths and interaction energies (kJ/mol), with the data indicating that N is a much stronger H-bond acceptor than O when integral to or conjugated with an sp2 π-system (Figure 41). For oxazole and methoxypyridine, the difference in energy between N and O acting as acceptors is more than 10 kJ/mol, supported by the prevalence of N acting as the H-bond acceptor in the CSD, summarized by the frequencies presented in Table 36.214 3.8.11. Oxygen Atoms and H-Bonding. These results were reinforced by calculated H-bond lengths and interaction energies (kJ/mol) between an oxygen atom bound to sp2 sites of unsaturation and H2O that showed reduced potential for O to function as an acceptor (summarized in Figure 42). For example, in esters the carbonyl oxygen always acts as the acceptor with the lone pair syn to the OR moiety, a slightly stronger acceptor.214 3.8.12. Isosterism between Heterocycles in Non-Prostanoid PGI2 Mimetics. A practical example of the effect of the difference in H-bonding associated with oxazole rings is provided by the series non-prostanoid PGI2 mimetics 48, 252, and 253 that inhibit ADP- and collagen-induced blood platelet aggregation in platelet-rich plasma in vitro.86,87,215,216 Potency is sensitive to the topology of the central oxazole ring with a 5-fold difference in the EC50 between the isomers 48 and 252. The weaker inhibitor 252 is comparable to the simple cis-olefin 253, suggesting that in this orientation the oxazole acts simply as a scaffolding element providing the optimal geometry to complement the PGI2 receptor. Data from a related series had formulated the hypothesis that the PGI2 receptor projects a 2556 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 43. Interactions between estradiol 17β-dehydrogenase and its substrate (A) and the inhibitor 256 (B). H-bond donor in the vicinity of the central oxazole ring. Consequently, the oxazole nitrogen atom was deduced to be acting as the acceptor in 48, a concept reflected in the intermolecular interactions observed in the single crystal X-ray structures of the oxazoles 48 and 252.215,216 In the solid state, the N atom of the central oxazole ring in both compounds engages in an intermolecular H-bond interaction with the carboxylic acid hydrogen of another molecule, leading to markedly different packing in the unit cell. However, the shape adopted by each individual molecule is essentially identical, providing an interesting example of exact isosterism, defined as “two molecules with close atom-foratom correspondence with regard to both internal coordinates and van der Waals radii”.217 3.8.13. Isosterism between Heterocycles in Estradiol 17βDehydrogenase Inhibitors. Another example where the subtle effect of H-bonding topology appears to affect potency is in a series of human estradiol 17β-dehydrogenase inhibitors where H-bonds between estradiol or estrone and the catalytically active histidines His198 and His201 were hypothesized to stabilize substrate complexes, as depicted in Figure 43A.218 In order to explore this concept, pyrazoles 256 and 257 and isoxazoles 258 and 259 were prepared as analogues of the ketones 254 and 255 and shown to be competitive inhibitors of estradiol 17β-dehydrogenase, with potency consistent with the postulated H-bond acceptor and donor patterns at both the A and D rings. For the A ring, the 2.5- to 6-fold difference in potency in favor of the OH compared to the OCH3 substituent supported the importance of a substrate H-bond donor interaction to the enzyme. For the D ring interactions, a potency difference of 1.9- to 7.3-fold was viewed as being consistent with the D ring functionality accepting a H-bond from the enzyme that could be reinforced by a D ring H-bond donor, realized only by the pyrazoles 256 and 257.218 The latter was interpreted as the pyrazole N-H donating a H-bond to His198, with His201 adopting a tautomeric config- uration in order to donate a H-bond to the pyrazole nitrogen atom. These SAR data are consistent with the C3-OH functioning as a H-bond donor to His209 and a C17 H-bond acceptor from His201 to either the ketone CdO of estrone or the pyrazole or isoxazole sp2 N atoms of the inhibitors, depicted in Figure 43B.218 Unfortunately, the isoxazoles isomeric with 258 and 259, which would have been an excellent test of the concept, were not synthesized. The potency difference between estrone and the pyrazole analogue was attributed to an additional H-bond donor interaction to His198 by the pyrazole N-H. 3.8.14. Role of Pyrimidine Nitrogen Atoms in Cathepsin S Inhibitors. An interesting example of the importance of the correct topology of a heteroatom for biological activity that illustrates the limits of the potential for isosterism between heterocycles is provided by a series of nonpeptidic heteroaryl nitriles that have been developed as inhibitors of cathepsins K and S.219 In these compounds, the nitrile moiety acts as an electrophile toward the catalytic cysteine thiol of the enzyme, reversibly forming a stable, covalent complex. Incorporation of the nitrile moiety at the 2-postion of a pyrimidine provided the potent and effective inhibitor 260 (Table 37). However, this arrangement results in an overactivation of the electrophilicity of the nitrile, leading to indiscriminate reactions with microsomal proteins. As part of the optimization process, a series of pyridines were examined in a systematic fashion with the anticipation of moderating nitrile electrophilicity, an exercise that provided fundamental insights into parameters associated with biological activity. Concordant with the underlying hypothesis, replacing the pyrimidine N-1 atom with a CH afforded the pyridine 261, a compound that exhibited 44-fold reduced potency toward 2557 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 37. SAR Associated with a Series of Inhibitors Cathepsins S and K Figure 44. Interaction between pyrimidine-based cathepsin inhibitors and the catalytic cysteine thiol that facilitates addition of the thiol to the activated nitrile. cathepsin S and 127-fold lower inhibition of cathepsin K. However, the isomeric pyridine 262 was inactive toward both cysteine proteases, leading to the conclusion that the pyrimidine N-3 interacts with the H of the cysteine thiol, facilitating addition to the nitrile moiety as depicted in Figure 44. When the pyrimidine N-3 atom is replaced with a C-H to afford the pyridine 262, not only is this function lost but a negative steric interaction between the ring CH and the SH is introduced.219 3.8.15. Heterocycles and Metal Coordination. An assessment of isosterism within a series of azoles designed to function as amide surrogates has been explored in the context of inhibitors of HIV-1 integrase in which biological activity is a function of the ability of the heterocycle to coordinate with one of the two Mg2þ atoms involved in catalysis.220-224 Azoles were selected over sixmembered heterocycles based on their ability to more readily adopt a coplanar arrangement with the additional metal chelating elements presented by a series of pyrido[1,2-a]pyrimidine and 1,6-naphthyridine-based integrase inhibitors. The selection of azoles introduced topological asymmetry that facilitated a precise analysis of the capacity of heteroatoms to engage Mg2þ based on the distinct topological preference for the presentation of the fluorobenzyl moiety relative to the pyrimidine ring (Figure 45). Enzyme inhibitory data for representatives of the pyrido[1,2-a]pyrimidine series are summarized in Table 38 which reveals the importance of presenting an azole nitrogen atom for coordination with Mg2þ, most evident in the comparison between the 1,2,4-oxadiazoles 267 and 268, an observation mirrored by the 1,6-naphthyridine series.221,223 In the pyrido[1,2-a]pyrimidine series, the thiazole series represented by 264 was selected for further optimization222 while the 1,3,4-oxadiazole ring (266) that performs modestly in this series was the most effective amide surrogate studied in the 1,6-naphthyridine series, reflecting subtle differences between the two chemotypes.223,224 3.8.16. Heterocycles and C-H Bonding. Hydrogen atoms bound to the sp2 carbon atoms of aromatic and heterocyclic rings have been established as weak C-H bond donors in small molecule X-ray crystallographic studies, an observation beginning to attract attention as direct and indirect mediators of ligand-target interactions in drug design.225,226 The observation of both inter- and intramolecular variants of this kind of H-bonding interaction in protein kinase inhibitors prompted ab initio calculations to evaluate the strength of C-H to water bonds, performed in conjunction with an analysis of the protein data bank (PDB), in order to understand the scope of the effect.226 The latter provided broader evidence for the existence of C-H H-bond interactions between ligands and proteins. Figure 45. Interactions between azole-substituted pyrido[1,2-a]pyrimidines and 1,6-naphthyridines and the catalytic Mg2þ atoms of HIV-1 integrase. Table 38. Structure-Activity Relationships for a Series of Azole-Substituted Pyrido[1,2-a]pyrimidine-Based Inhibitors of HIV-1 Integrase The results of the ab initio studies for a series of ring systems prevalent in drug design are compiled in Table 39, with the energy of the C-H H-bond donor activity indexed to H2O and CH4 as the two bookends. Not surprisingly, these hydrogen atoms are weaker H-bond donors than H2O but stronger than CH4, and heterocycles offer advantage over a phenyl ring, with strength dependent on the regiochemical relationship of the C-H to the heteroatoms. While unlikely to dominate a small molecule-protein interaction, these weak interactions would be anticipated to play an augmenting role and examples are beginning to be documented. 3.8.17. Heterocycle C-H Bond Donors in GSK3 Inhibitors. The serine/threonine kinase glycogen synthase kinase 3 (GSK3) is known to be involved in several cellular signaling pathways and represents a potential molecular target for type 2 diabetes and Alzheimer’s disease, where GSK3 levels have been shown to be elevated. GSK3 also has proapoptotic activity and may be involved in neuronal cell death, while inhibitors may mimic the action of mood stabilizers such as lithium and valproic acid, suggesting potential for 2558 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 39. Calculated H-Bond Donor Interaction Energies between a C-H and H2O Compared to H2O and CH4226 Figure 46. Key H-bonding interactions between 271 and glycogen synthase kinase 3. Table 40. SAR Associated with a Series of Glycogen Synthase Kinase 3 Inhibitors the treatment of bipolar mood disorders. An X-ray crystal structure of the enzyme was solved in 2001, facilitating structure-based design and leading to the development of a seam of biological activity associated with structurally diverse inhibitors. The 4-aminoquinazoline derivative 271 was a potent early lead, Ki = 24 nM, that exhibited inhibition kinetics consistent with the compound acting as a competitive inhibitor of ATP binding (Table 40).227 An X-ray cocrystal structure confirmed the mode of inhibition and revealed three H-bonding interactions between the enzyme and 271, which adopted an overall planar topography in the active site, as depicted in Figure 46. However, much of the fundamental SAR associated with 271 appeared to be cryptic in nature. The poor activity of the isoxazole 272 was explained by the loss of a H-bond donor moiety, while the 4-fold reduced activity of pyrazole 273 was attributed to the loss of an important hydrophobic interaction associated with the CH3 moiety 2559 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry Figure 47. Drug-target interactions between the thiazole 277 and glycogen synthase kinase 3. Figure 48. Binding interactions between Janus kinase 2 and the inhibitor 278 and the structure of two analogues 279 and 280. of 271 (data summarized in Table 40).227 However, replacing the pyrazole ring of 271 by a triazole (274), which preserves the H-bond donor capability, resulted in 1000-fold reduction in potency while removing the CH3 group, to afford 275, restored potency by 100-fold, a result that contrasts markedly with the data for the related pyrazoles 271 and 273. Adding to the enigma, the quinoline 276 was found to be 100-fold less active than 271, with a Ki of 2.5 μM.227 A careful analysis of this series based on an assessment of the preferred conformations of the azole moieties in relation to the quinazoline or quinoline heterocycle and an appreciation of H-bonding patterns, including C-H H-bond donors, provided a coherent explanation for the data that are summarized in Table 41. 3.8.18. Evolution of GSK3 Inhibitors. Taking advantage of these observations and seeking new active inhibitors of GSK3, the thiazole 277 was designed based on modeling that revealed a planar conformation preferred by 9 kcal/mol, attributed to a productive N to S σ* stabilizing interaction that is a function of a partial positive charge on S (þ0.35) and a partial negative charge on N (-0.65) (Figure 47).227 A heteroaryl C-H H-bond donor interaction to an enzyme backbone carbonyl oxygen atom was also invoked, optimal when the H-bond donor is bound to a carbon adjacent to a heteroatom (Figure 47). This compound was synthesized and tested, displaying a Ki of 150 nM, just 6-fold weaker than the pyrazole 271, an observation attributed to the weaker C-H H-bond donor in 277 compared to the pyrazole NH. An X-ray cocrystal structure confirmed the predicted interactions, providing the first example where CH 3 3 3 X H bonds play an important role in drug-target binding.227 3.8.19. Janus Kinase 2 (JAK2) Inhibitors. AZ-960 (278) is a potent JAK2 inhibitor, IC50 e 3 nM, that acts as a competitive inhibitor of ATP, with the orientation in the binding site depicted in PERSPECTIVE Figure 48.228,229 In this series, a pyrazine was shown to be an effective isostere of the pyridine while a thiazole was examined as a pyrazole replacement, pursuing a hypothesis based on the proposed binding mode and concepts developed from the earlier observations described above for GSK3 inhibitors. In the event, pyrazole 279 and thiazole 280 showed comparable potency attributed to a productive N-S interaction to replace the C-H H-bond donor interaction between the pyrazole and pyrazine in 278 and 279.228,229 The unique properties of sulfur in heterocyclic ring systems have been appreciated more broadly as a means of influencing conformational preferences. A recent example took advantage of establishing a no f σ* interaction between a pyrimidine nitrogen and a thiazole sulfur atom to bias conformational constraint in a series of p38R MAP kinase inhibitors.230,231 In a successful attempt to optimize the thiazole 281, for which the X-ray cocrystal with the enzyme suggested an interaction between the thiazole S atom and the proximal amide carbonyl lone pair, 231 the pyrimidine 282 emerged as a potent p38R MAP kinase inhibitor, IC50 = 7 nM. An X-ray cocrystal of 282 bound to the enzyme revealed coplanarity between the thiazole and pyrimidine rings, consistent with the proposed no f σ* interaction. Confirmation was obtained from single crystal X-ray structures of 283 and 284 in which the more potent 283 (IC50 = 46 nM) adopted a conformation with a short (2.90 Å) contact distance while the less potent 284 (IC50 = 223 nM) crystallized with the topology shown, also stabilized by a no f σ* interaction that favors the alternative conformation that is not complementary to the topology of the enzyme active site.231 This kind of n f σ* donation to sulfur that creates close contacts between the atoms has been analyzed theoretically for S 3 3 3 O interactions232 and recognized as contributing to conformational preorganization and, hence, biological activity in the factor Xa inhibitor 285,233 the Aurora A and B kinase inhibitor 286,234 the nucleoside analogue tiazofurin (287) and related compounds,235-238 the angiotensin II receptor antagonist 288,239 and the proton pump inhibitor rabeprazole (289).240 In the case of 286, 287, and 288, the corresponding oxygen analogues have been shown to be markedly less potent, demonstrating the importance of selecting the correct azole moiety and defining the limits of isosteric replacement between heterocycles. 2560 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 41. Factors Underlying the Conformational Preferences of a Family of Glycogen Synthase Kinase 3 Inhibitors Figure 49. Charge demand is defined as the fraction of π-charge transferred from a negatively charged trigonal carbon atom to the adjacent X group. 3.8.20. Electron Demand of Heterocycles and Applications. The electron withdrawing properties of heterocycles, which are dependent on the identity of the heterocycle, the site of attachment, and the nature and position of substituents, have been exploited extensively in drug design. Two of the most prominent applications include the activation of carbonyl moieties to electrophilic species that readily react with the catalytic serine of serine proteases and related serine hydrolases to afford mechanism-based inhibitors and the acidification of amine or amide moieties to improve H-bond donor properties, culminating in carboxylic acid isosterism in the case of sulfonamide-based antibacterial agents. In an effort to quantify electron withdrawal, the concept of charge demand has been formulated, defined as the fraction of π-charge transferred from a negatively charged trigonal carbon atom to the adjacent X group, as depicted in Figure 49.241-244 A ranking of resonance electron withdrawing capacity of a range of functional groups and heterocycles of interest to medicinal chemists, measured by 13C NMR chemical shifts of trigonal benzylic carbanions, is compiled in Table 42. 3.8.21. Heterocycles and Activation of a CdO in Serine Protease Inhibitors. One aspect of the design of serine protease inhibitors has focused on presenting the enzyme with a substrate mimetic in which the scissile amide bond is replaced with an electrophilic carbonyl element to which the catalytic serine hydroxyl reacts to form a stable but unproductive tetrahedral intermediate. The equilibrium in favor of the adduct is a function of the electrophilicity of the CdO moiety, and peptidic aldehydes were adopted as the vehicle for the initial examination of this concept.245 Subsequent refinement probed trifluoromethyl ketones and pyruvate derivatives, the latter providing an opportunity for the incorporation of structural elements designed to interact more extensively and productively with the S0 pockets. Further evolution along this path of inquiry focused on a series of tripeptidic, mechanism-based inhibitors of human neutrophil elastase (HNE) that incorporated heterocycles as the carbonyl activating element.246-252 R-Ketoamides were included in 2561 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 42. Charge Demand Associated with Functional Groups and Heterocycles Arranged in Order of Increasing Electron Withdrawal Figure 50. Key interactions between a tripeptidic ketobenzoxazole derivative and HNE. Figure 51. Contact interactions between nitro and functional groups abstracted from the Cambridge Structural Database.256 this study as comparators, and inhibitory potency was found to correlate with the electrophilicity of the carbonyl moiety (results summarized in Table 43).247 These heterocyclic carbonyl-activating moieties were considered to offer several advantageous opportunities for drug design, including the potential for unique interactions with enzyme and the ability to probe interactions with S0 sites, while the size of the heterocycle was considered to offer potential to sterically interfere with metabolism of the carbonyl moiety.246-248,252 Subsequent studies examining an oxadiazole activating element found that activity was quite sensitive to the identity of the heterocycle with the 1,3,4-oxadiazole 290, a highly potent inhibitor of HNE, Ki = 0.025 nM, but the isomeric 1,2,4-oxadiazole 291 was 20-fold weaker, Ki = 0.49 nM.249 The 1,3,4-oxadiazole was subsequently incorporated into ONO-6818 (292), an orally bioavailable, nonpeptidic inhibitor of HNE advanced into clinical trials.250 An X-ray cocrystal structure of a benzoxazole derivative bound to HNE revealed the key enzyme-inhibitor interactions, confirming the addition of the catalytic serine hydroxyl to the activated carbonyl moiety and revealing the development of a productive H-bonding interaction between the benzoxazole N atom and the NH of the imidazole of the catalytic histidine (Figure 50).246 Fatty acid amide hydrolase (FAAH) is a serine hydrolase responsible for degrading endogenous lipid amides, including anandamide and related fatty acid amides that have been identified as neuronal modulators. Heterocycles have been productively examined as activators of carbonyl moieties in mechanism-based inhibitor design252 with the focus directed toward a series of 2-ketooxazole derivatives.253,254 In these studies, the electronic properties of the oxazole moiety were modulated by the introduction of substituents capable of indirectly influencing carbonyl electrophilicity, with the structure-activity relationships captured in Table 44 demonstrating the effects on potency. FAAH inhibitory activity correlated nicely with the Hammett σ constant for substituents, a fundamental structure-activity relationship that allowed both deduction and prediction of the physicochemical nature of the oxazole subsituent. For example, the 5-CO2H derivative was deduced to bind as CO2- under the assay conditions based on the σp of 0.11 for the charged species versus a σp of 0.44 for CO2H.253,254 Similarly, it was concluded that the 5-CHO and 5-COCF3 analogues bind as the hydrates, observed as the species in solution by 1H and 13C NMR, providing the first estimates of σp for these substituents (0.26 for CH(OH)2 and 0.33 for C(OH)2CF3).253,254 3.9. Isosteres of the Nitro Group. The nitro moiety is a small, moderately polar substituent255 capable of H-bonding, with several such contacts observed in structures in the CSD, as summarized in Figure 51.256 Most typically, the nitro group is encountered as a substituent on aryl or heteroaryl rings where it polarizes the 2562 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry Table 43. Structure-Activity Relationships Associated with a Series of Tripeptidic Mechanism-Based Inhibitors of HNE PERSPECTIVE Table 45. SAR Associated with a Series of Human Epidermal Growth Factor Receptor Kinase Inhibitors Table 44. Structure-Activity Relationships Associated with a Series of Ketooxazole-Based Inhibitors of Fatty Acid Amide Hydrolase (FAAH) A successful and more recent example of the replacement of a nitrophenyl moiety by a pyridine is provided by a series of human epidermal growth factor receptor kinase inhibitors for which the lead molecule 295 contained a nitrophenyl moiety. 259 In these inhibitors, SAR suggested a role for the nitro group as a H-bond acceptor that was nicely mimicked by the pyridine 296 while attempts to replace the NO2 group with alternative substituents were much less successful (data summarized in Table 45).259 π-system, and a number of protein-ligand interactions involve the πsystem of aromatic rings. However, nitro-substituted benzene derivatives are associated with toxicity as a function of partial reduction to the hydroxylamine which can undergo metabolic activation to an electrophilic nitroso species. Identifying suitable replacements for nitro-substituted aryl or heteroaryl rings has proven to be challenging, with pyridine the most common isostere, although a carboxylate has been shown to function as a nitro isostere in an inhibitor of ribonucleotide carboxylase.257 In an early study of nitro isosteres, pyridine was probed as a replacement for a nitrophenyl in the context of the β-adrenergic antagonist 293 with the 4-pyridyl analogue 294 10-fold more potent.258 Nimesulide (297) is a COX-2-inhibiting NSAID first prepared in 1974 but never marketed in the U.K., U.S., and Canada because of a poor safety profile (Table 46). 260 The drug was subsequently withdrawn in Spain and Finland in 2002-2003 because of idiosyncratic cases of hepatotoxicity which occurred at the rate of 9.4 cases per million patients treated, and marketing authorization was suspended in Ireland in 2007 because of six cases of liver transplant following the use of nimesulide-containing products. Both nimesulide and its amine metabolite cause mitochondrial toxicity to isolated rat hepatocytes, attributed to oxidation of the 1,4-diaminobenzene metabolite to an electrophilic diiminouinone. 260 In an attempt to identify safer analogues, 2563 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 46. Structure-Activity Relationships Associated with 297 and Analogues Figure 53. TDP-L-rhamnose synthase-mediated reduction of a ketone and a structurally analogous difluoroethylene derivative. Figure 52. Synopsis of carbonyl isosteres. the pyridine 298 was synthesized and found to retain intrinsic potency while preventing metabolic activation, and this compound was active in an animal model of inflammation (Table 46).261,262 Further optimization explored substitution of the ether oxygen atom by NH and adding a Br substituent to the phenyl ring to afford 299. However, it is noted that this molecule contains an embedded 1,2-phenylenediamine element that has the potential to undergo oxidation to the alternative ortho diiminoquinone to that observed with the metabolite of 297. 3.9.1. Nitro Isosteres in R1a Adrenoreceptor Antagonists. Isosteres of a nitro substituent were sought in a series of selective R1a adrenoreceptor antagonists targeted for the treatment of benign prostatic hyperplasia, a urological disorder, based on the observation that the R1R adrenoreceptor mediates contraction of lower urinary tract and prostate smooth muscle.141,142,263,264 Although the lead dihydropyridines, represented by 300, were related to niguldipine, they showed no Ca2þ-channel blockade but exhibited poor oral bioavailability due to oxidation to the pyridine, leading to the adoption of a dihydropyrimidin-2-one as the core scaffold. Nitrophenyl mimetics were sought in he context of 301 in order to remove an additional metabolic liability, an exercise that identified the 3,4-diflluorophenyl moiety found in 302 as a suitable and effective surrogate.141,142,263,264 3.10. Isosteres of Carbonyl Moieties. 3.10.1. Ketone Isosteres. Simple ketones and aldehydes typically have a low prevalence in drugs and candidates because of their potential chemical reactivity and susceptibility to engaging in a reduction/oxidation pathway in vivo. Some of the more prominent ketone isosteres are captured in Figure 52, including substituted ethylenes in which the electronegative substituents are designed to replace the oxygen atom lone pairs. Both F and CN preserve the geometry and electronics of a CdO moiety, but both motifs present potential issues associated with inherent chemical reactivity, exemplified by the TDP-L-rhamnose synthase-mediated reduction of a difluoroethylene moiety, as summarized in Figure 53.265 Sulfoxide, sulfone, sulfoximine, and oxetane moieties have been probed as ketone isosteres, with the tetrahedral geometry of the former three of potential advantage dependent upon context. The sulfone moiety functioned as an effective ketone isostere in a series of HCV NS5B polymerase inhibitors that bind near the interface of the palm and thumb subdomains of the enzyme and proximal to the nucleotide binding site, referred to as the primer grip.266 An X-ray cocrystal revealed that the CdO moiety of 303 engaged the NH of Tyr448, leading to an examination of the effect of probing a sulfone as an isostere, with recognition a priori of the potential of this moiety to establish a second H-bond with the NH of Gly449. In the event, the sulfone analogue 304 demonstrated improved binding affinity for the enzyme with a 19-fold shift in the KD and a 14-fold improvement in potency in a cell-based replicon assay.266 3.10.2. Oxetane as a CdO Isostere. A series of oxetane derivatives were prepared as part of a broader effort to explore their inherent physical and conformational properties, with a focus on establishing isosterism with the carbonyl moiety based on the nonpuckered shape of the oxetane ring (Figure 54).118-120,267 All of the compounds examined were stable over the pH range 1-10, including the azetidines. In addition, the oxetane oxygen atom expresses a similar capacity to the CdO moiety to accept a H-bond: the pKHB for oxetane is 1.36 which is comparable to a pKHB for cyclopentanone of 1.27.268,269 However, oxetanes are more lipophilic than their analogous CdO derivatives and differentially affect electronic properties, exemplified by the 2-oxa-6-azaspiro[3.3]heptane ring 2564 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE good oral bioavailability in the dog, an advance on 309 which was poorly bioavailable.272,273 Figure 54. Isosteric relationships between carbonyl-containing functionality and oxetanes. 3.10.4. Fluorine as a CdO Isostere in FKBP12 Mimetics. V10367 (310) and related compounds mimic the FKBP12-binding portion of FK506 and were examined as potential neurotrophins, an activity observed for FK506 in vitro and in vivo. Replacement of the keto carbonyl with a gem-difluoro moiety afforded 311 which displayed Ki = 19 nM as an inhibitor of FKBP12 rotamase activity, with potency comparable to that of 310.274 Analysis of an X-ray cocrystal structure revealed that one fluorine atom is close (3.18 Å) to the phenolic OH of Tyr26 of FKBP12 that forms a H-bond with the ketone CdO of 310 while the second fluorine interacts with a hydrogen atom of the aryl ring of Phe36, 3.02 Å away.274 Figure 55. Binding interactions between factor VIIa and inhibitors 305 and 306 and the structure of a fluorobenzene-based analogue 307. system, a potential morpholine isostere, which is physically more slender and more basic, pKa = 8, than morpholine, pKa = 7.118-120,267 3.10.3. Fluorine as a CdO Isostere in Factor VIIa and Thrombin Inhibitors. A C-F moiety has been examined as a potential CdO isostere in the context of the pyridinone-based factor VIIa inhibitors 305 and 306 in which the amide CdO and proximal NH engage in complementary H-bonding interactions with Gly216 of the enzyme, as summarized in Figure 55.270,271 Although replacement of the pyridone with a fluorobenzene ring modestly compromised potency, an X-ray cocrystal structure of 307 bound to factor VIIa at 3.4 Å resolution revealed a close contact between the F atom and the NH of Gly216, interpreted as a H-bond that was anticipated during the design phase.270,271 This motif performed with similar effectiveness in a series of thrombin inhibitors with 308, Ki = 1.2 nM, a potent analogue derived from the pyridone 309, Ki = 4 nM, that demonstrated 3.10.5. Amide and Ester Isosteres. Amide and ester isosteres have been extensively studied, with a focus on amides in the context of peptidomimetics, while seminal studies of ester isosteres examined with the benzodiazepines 312 and 313 were subsequently extended into muscarinic agonists based on arecoline (314), probed as potential agents for the treatment of Alzheimer’s disease.275,276 Amide isosteres have typically been of interest as a means of modulating polarity and bioavailability, while ester isosteres have frequently been developed to address metabolism issues since esters can be rapidly cleaved in vivo. A synopsis of the amide and esters isosteres is presented in Figure 56 which exemplifies azole heterocycles among the most common and prominent replacements, although more recent design efforts have focused on mimetics that offer greater conformational flexibility. 3.10.6. Trifluoroethylamines as Amide Isosteres. The trifluoroethylamine moiety, CF3CH(R)NHR0 , was studied initially as an amide isostere in the context of peptide-based enzyme inhibitors 2565 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 56. Synopsis of amide and ester isosteres. Figure 57. Comparison of two potential motifs by which the trifluoroethylamine moiety can act as an isostere of an amide moiety in peptide-based molecules. In part B the trifluoroethylamine is introduced in register directly mimicking the amide moiety in part A, while in part C the trifluoroethylamine is incorporatred with partial retroinversion of the reading frame. Figure 58. Binding interactions between HIV-1 protease and inhibitors. (Figure 57A) where it can be incorporated in register (Figure 57B) or with partial retroinversion of the reading frame (Figure 57C).277-283 In this context, the trifluoroethylamine can be considered to be structurally similar to the tetrahedral intermediate associated with peptide proteolysis. More recently, the trifluoroethylamine element has been adopted as an effective amide isostere in drug discovery campaigns, with compounds incorporating this functionality now entering clinical trials.284,285 Functional mimicry is based on the trifluoromethyl moiety reducing the basicity of the amine without compromising the ability of the NH to function as a H-bond donor. In addition, the CF3CH(R)NHR0 bond is close to the 120° observed with an amide, and the C-CF3 bond is isopolar with a CdO.277-283 Of potential advantage depending on context, the trifluoromethylethylamine moiety confers conformational flexibility that may improve complementarity with a target protein although at the expense of introducing a stereogenic center. The pentafluoroethylamine moiety, CF3CF2 CH(R)NHCHR0 , performs in a functionally similar fashion.284,285 3.10.7. Trifluoroethylamines as Amide Isosteres in Cathepsin K Inhibitors. Cathepsin K is a lysosomal cysteine protease in osteoclasts responsible for bone degradation during remodeling, with inhibitors preventing bone resorption and offering potential in the treatment of osteoporosis.284,285 The cathepsin K inhibitor L-006235 (315) presents a nitrile functionality to the enzyme that reacts reversibly with the catalytic 2566 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry cysteine that, although exhibiting good pharmacokinetic properties, was poorly selective for cathepsin K compared to the related enzymes cathepsins B, L, and S. This profile was attributed to the lysosomotropic nature of 315 which is both basic and lipophilic. Optimization led to the identification of L-873724 (316), a compound in which the amide moiety of 315 was replaced by a trifluoroethylamine element, resulting in improved selectivity but poorer pharmacokinetic properties. Odanacatib (317) was the product of further refinement that solved both problems, with the fluorinated valine blocking hydroxylation and the quaternary cyclopropyl moiety at P1 reducing the propensity for amide hydrolysis.284,285 Compound 317 is currently in phase 3 clinical trials. PERSPECTIVE in liver microsomes in vitro by a nonoxidative pathway releasing, in the case of 320, the 2-aminopyridine 321 and cyclopropanecarboxylic acid 317, a simple molecule associated with toxicity in vivo.288 A range of effective isosteres were developed that offered improved metabolic stability in vitro, as summarized in Table 47.287 3.11. Ether/Sulfone and Glyoxamide/Sulfone Isosterism. 3.11.1. Ether/Sulfone Isosterism in HIV-1 Protease Inhibitors. 3.10.8. Trifluoroethylamine as an Amide Replacement in the HCV NS3 Inhibitor Telaprevir. An interesting example where examination of the trifluoroethylamine moiety as an amide isostere markedly affected target specificity and selectivity is provided by the tetrapeptidic, mechanism-based inhibitor of HCV NS3 protease, 12.286 Compound 12 inhibits HCV NS3 with an IC50 of 70 nM and is an effective antiviral agent, EC50 = 210 nM in the replicon.39 However, telaprevir also inhibits cysteine proteases, including cathepsin B with an IC50 of ∼210 nM. Although cathepsin S inhibition data have not been reported for 12, replacing the P4 amide with a trifluoroethylamine moiety produced the potent cathepsin S inhibitors 318 (IC50 = 2 nM) and 319 (IC50 = 0.6 nM) in which activity is largely insensitive to the absolute configuration.286 Most interestingly given that the structural changes are remote from the active site of HCV NS3, both compounds are much less active in the HCV replicon with only 34% and 29% inhibition observed at 25 μM for 318 and 319, respectively. Cathepsin S activity has been implicated as an underlying cause of aspects of allergic disorders and both Alzheimer’s and autoimmune diseases. 3.10.9. Amide Isosteres in Adenosine2B Antagonists. The amide 320 is a potent adenosine 2B antagonist, Ki = 4 nM, explored for its potential to prevent adenosine-mediated inflammation in asthma.287 However, simple amides were cleaved Saquinavir was the first HIV-1 protease inhibitor to be approved, but this compound, although highly potent with IC50 = 0.23 nM, is poorly bioavailable, attributed to the peptidic nature of the molecule and the number of NH bonds (Figure 58A). Replacing the asparagine moiety embedded within saquinavir with a 3(R)-tetrahydrofuranylglycine moiety improved potency several-fold, IC50 = 0.05 nM (Figure 58B), while removal of the quinoline moiety decreased potency markedly, IC50 = 160 nM (Figure 58C).289,290 Taking a cue from these data, Ghosh replaced the (R)-3-THF moiety found in amprenavir (323), Ki = 0.6 nM, with a cyclic sulfone to afford 324, a compound that maintained inhibitory potency, Ki = 1.4 nM. In models of 324 bound to HIV-1 protease, the cyclic sulfone oxygen atoms were proposed to accept H-bonds from both the Asp29 and Asp30 NHs, as depicted in Figure 59A. Further optimization took advantage of this observation and led to the design of a bicyclic ether ring system as an effective and more lipophilic sulfone isostere, initially explored in 325 as a prelude to identifying the highly potent HIV-1 protease inhibitor darunavir (326), licensed in the United States in June 2006. The design emphasis in arriving at 326 focused on optimizing essential interactions between the inhibitor and the backbone of HIV-1 protease, captured in Figure 59B, with a view to minimizing the potential for resistance.289,290 3.11.2. Sulfone/Glyoxamide Isosterism in HIV Attachment Inhibitors. The indole glyoxamides 327 and 328 are potent inhibitors of HIV-1 replication in cell culture, EC50 = 7 nM and EC50 < 5 nM, respectively, that act by interfering with the binding of viral gp120 2567 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry to the host cell CD4 receptor.291,292 The glyoxamide moiety typically adopts an orthogonal arrangement of the two carbonyl groups in order to minimize nonbonded interactions while deploying the dipoles in the most stable orientation. A sulfone moiety was postulated as an effective mimetic based on 3D structural analysis, and although a potent antiviral, EC50 = 7 nM, 329 was less impresssive than the structurally analogous glyoxamide 328, EC50 < 5 nM.292 An attempt to compensate for the topological differences between the two chemotypes examined a series of biaryl derivatives represented PERSPECTIVE generically by 330 with only limited success, since this series generally exhibited poor antiviral activity.293 Table 47. Structure-Activity Relationships Associated with a Series of Adenosine 2B Antagonists 3.12. Urea Isosteres. 3.12.1. Urea Isosteres in Histamine Antagonists. The development of histamine H2 antagonists fostered a considerable understanding of the design of isosteres of ureas and thioureas, with classic studies representing an early application of the careful and detailed analysis of physical chemistry properties to drug design.294 Metiamide (331) was used as the lead compound to design cimetidine (332) in which the thiourea was replaced by a cyanoguanidine.294 A 2,2-diamino-1-nitroethene functioned as an effective urea isostere in ranitidine (333), while later studies focused on 1,2,5-thiadiazole oxides related to 334 as potent H2 antagonists.295,296 3.12.2. Urea-Type Isosteres in KATP Openers. Pinacidil (335), a KATP opener studied clinically for the treatment of hypertension, attracted the attention of a group focused on optimizing its bladder smooth muscle relaxant properties as a potential Figure 59. Proposed binding interactions between HIV-1 protease and the sulfone-based inhibitor 324 (A) and key binding interactions observed between HIV-1 protease and 326 in the X-ray cocrystal structure (B). 2568 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry therapy for urge urinary incontinence. A series of diaminosquarate derivatives 336 was developed based on the recognition of an isosteric relationship with the cyanoguanidine moiety of 335.297 It was found that a 2-ethyl substituent on the aryl ring of diaminosquarate derivatives enhanced bladder potency by 6-fold, leading to the emergence of WAY-133537 (337) as a lead candidate.297 The squaramide 337 exhibits 70% oral bioavailability in the rat, is clean in an AMES test, and revealed no significant drug-related toxicities in rats at doses up to 200 mpk. In vivo, the compound inhibited spontaneous bladder contractions at doses lower than that at which hypotensive effects were manifest.297 An alternative urea/cyanoguanidine isostere is found in ZD-6169 (338), another bladder-selective KATP opener evaluated clinically for urge urinary incontinence.298 PERSPECTIVE Figure 60. Calculated energies associated with the four lowest energy nitroketene aminal conformers. 3.12.4. Additional Squaric Acid Urea Isosteres. Squaric acid derivatives are well represented in drug design and include the mitogen-activated protein kinase-activated protein kinase 2 inhibitors 344 and 345,301 the marketed histamine H2 antagonist pibutidine (347), an isostere of lafutidine (346), and 349, a very late antigen-4 (VLA-4) integrin antagonist designed after 348. 302 By use of similar fundamental design principles, the chiral squaric diamide 350 is an effective organic catalyst whose design is based after the analogous urea. 303 3.12.3. Urea Isosteres in CXCR2 Antagonists. 3,4-Diaminocyclobut-3-ene-1,2-diones were also probed as urea mimetics in the context of the CXCR2 ligand 339, leading to the identification of the potent CXCR2 antagonists 340-342.299 These compounds demonstrated good activity in a chemotaxis assay in vitro with the phenyl derivative 342 identified as the most potent agent. Caco-2 permeability and aqueous solubility were better for the alkylamine analogues 340 and 341 compared to the phenyl derivative 342, while all demonstrated good metabolic stability in HLM.299 The diaminocyclobut-3-ene-1,2-dione SCH-527123 (343) is a dual CXCR2/CXCR1 antagonist (CXCR2 IC50 = 2.6 nM; CXCR1 IC50 = 36 nM) that inhibits human neutrophil chemotaxis in vitro induced by CXCL1 or CXCL8 and was viewed as possessing potential for the treatment of inflammatory diseases.300 Phase IIa trials of 343 for COPD and asthma have been completed, and two 500-patient phase IIb trials were recently initiated. 3.12.5. Urea/Thiourea Isosteres in Factor Xa Inhibitors. The disubstituted lactam 351 is a potent inhibitor of the serine protease factor Xa, IC50 = 110 nM, for which effective replacements of the thiourea were sought in order to avoid the potential for toxicity.304 A careful analysis of the conformational preferences of the four lowest energy nitroketene aminals was conducted (summarized in Figure 60) and compared to thiourea, both of which were found to favor the anti-syn1 conformation and suggesting the potential for effective isosterism. However, the nitroketene aminal 352 was a 60-fold weaker inhibitor of factor Xa, IC50 = 6400 nM, necessitating further optimization of both the thiourea mimetic 2569 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 61. Synopsis of guanidine and amidine isosteres examined in the context of P1 elements in factor Xa inhibitors.313 and the aniline moiety, an exercise that ultimately afforded the potent factor Xa inhibitor 353, IC50 = 20 nM.304 3.13. Guanidine and Amidine Isosteres. Interest in identifying isosteres of the amidine and guanidine functionality has largely been driven by attempts to develop inhibitors of the serine proteases that constitute the coagulation cascade and that includes thrombin and factor Xa, both of which recognize an arginine at P1 of substrates.305,306 Guanidines and amidines are highly basic entities that are protonated at physiological pH, which leads to poor membrane permeability, a significant impediment to developing orally bioavailable compounds. Basicity can be reduced from a pKa of 13-14 by replacement of an adjacent CH2 with either a carbonyl moiety to afford an acyl guanidine, pKa ≈ 8, or an oxygen atom, pKa ≈ 7-7.5. These modifications, which represent isosteric replacement of a CH2, have the potential to significantly compromise potency depending on the application. However, acylguanidines have been successful in developing a family of histamine H2 agonists307,308 while oxyguanidines are useful P1 surrogates in thrombin inhibitors, as demonstrated by RWJ-671818 (354), a compound advanced into phase 1 clinical studies.272,273,309-311 Although prodrugs have also been extensively explored and offered a solution for some drug candidates, alternative structural elements designed to mimic aspects of guanidine have been devised with greater overall success. Typically, these inhibitors rely upon optimized interactions at other subsites of the enzymes in order to fully secure potency and selectivity, with clinically effective, orally bioavailable inhibitors of the coagulation enzymes, particularly factor Xa, in late stage clinical development.312 3.13.1. Arginine Isosteres in Factor Xa Inhibitors. The wide range of arginine mimetics compiled in Figure 61 were examined in the context of P1 elements in factor Xa inhibitors and provide a synopsis of the more prominently successful arginine isosteres.313 Of particular interest are the neutral elements, with the 3-chlorophenyl moiety offering potency, Ki = 37 nM, comparable to that of the 3-aminophenyl, Ki = 63 nM, 10-fold weaker than the 3-aminomethyl, Ki = 2.7 nM, although all are markedly less potent than the 3-amidino prototype which displayed Ki = 0.013 nM.313 The 4-methoxy analogue exhibited good potency, Ki = 11 nM, and this P1 moiety is found in the clinically relevant factor Xa inhibitor apixaban (355).312 More recently, chlorothiophenes have emerged as useful P1 elements for factor Xa and thrombin inhibitors.314,315 Pyridazinone 356, originally prepared as a phosphodiesterase-3 inhibitor with potential as a positive inotropic agent, was identified by screening as a weak factor Xa inhibitor, IC50 = 1.1 μM (Figure 62).314 An X-ray cocrystal of 356 with the enzyme established the binding mode with the chlorothiophene establishing a halogen bonding interaction with the π-cloud of Tyr228, 2570 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 48. Acidity of a Series of Diphosphonates Compared to Diphosphate Figure 62. Key interactions between factor Xa and the pyridazinonebased inhibitor 356. captured in Figure 62.314 Optimization afforded the more potent inhibitor 357, IC50 = 5.9 nM, and several additional examples have appeared in the literature.312,315 Table 49. Acidity of Phenyl Phosphate and a Series of Phosphonate Analogues compd The diaminosquarate moiety has been explored successfully as a guanidine mimetic in the context of the arginine-derived peptidomimetic 358, an inhibitor of the interaction between the HIV-1 transcription regulator Tat and the Tat-responsive RNA element TAR.316 The guanidine 358 binds to HIV-1 TAR RNA with Kd = 1.8 μM, while the squaric acid diamide analogue 359 is a 4-fold weaker ligand, Kd = 7.7 μM, providing the first example of this moiety acting as a functional guanidine isostere.316 3.14. Phosphate and Pyrophosphate Isosteres. One of the most challenging functionalities to mimic in the design of drugs for development has been the phosphate or pyrophosphate functionality.317 For in vitro inhibitors, a phosphonate is a useful and stable phosphate mimetic that can be improved by difluorination of the R-C atom to increase the acidity to more closely match that of the phosphate moiety.318 Phosphate isosteres have been explored primarily in the context of nucleotide analogues and phosphatase inhibitors, with a wide range of isosteres that offer less severe acidic functionality explored in an effort to find surrogates compatible with oral absorption. This initiative has enjoyed only limited success, since a general solution has not been identified and solutions to individual problems are rare. Consequently, prodrugs have been the usual resort in situations where phosphates or phosphonates are an absolute requirement pKa2 PhOP(O)(OH)2 6.22 PhCH2P(O)(OH)2 7.72 PhCH(F)P(O)(OH)2 6.60 PhCF2P(O)(OH)2 5.71 for drug-target interactions, and there are several examples of clinically useful prodrugs either marketed or in development. Nevertheless, there have been some productive advances, most notably in the context of HIV-1 integrase strand transfer inhibitors, where a wide range of successful mimetics of the transition state in phosphate hydrolysis have been identified. Of particular interest are a series of hydroxylated pyrimidinones that, when appropriately configured, extend isosterism to that of the pyrophosphate moiety. 3.14.1. Phosphate and Pyrophosphate Mimetics. The lower acidity of phosphonates often leads to poor mimicry of phosphates, rectified by judicious substitution with electronegative substituents, with mono- or difluorophosphonates more closely mimicking the pKa of phosphate (data compiled in Tables 48 and 49).318-321 However, the highly acidic nature of fluorophosphonates has limited their application and utility in drug design largely to biochemical evaluation in vitro. 3.14.2. Phosphate Isosteres in PTP-1B. Protein tyrosine phosphatase-1B (PTP-1B) is a negative regulator of the insulin and leptin signal transduction pathways, and inhibitor design has focused on peptide-based recognition fragments that incorporate mimetics of phosphotyrosine. Compounds presenting dicarboxylic acids, related polyacidic analogues, and polar functionality as well as PhCF2P(O)(OH)2 derivatives are represented among isosteres that have been identified as effective, competitive PTP1B inhibitors in vitro, moieties summarized in Figure 63.322,323 In an interesting example of inhibitor design, an analysis of the overlay of the two inhibitor motifs depicted in Figure 64 led to the proposal of the novel isothiazolidinone-based inhibitor 360.322-325 Interestingly, this chemotype was arrived at independently based on X-ray data of the small ligand 361 in which the ortho methoxy substituent increased potency by promoting orthogonality of the heterocycle ring.326 2571 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 63. Synopsis of protein tyrosine phosphatase-1B (PTP-1B) inhibitor motifs. optimize drug-target interactions.324,325 Although both 366 and 367 are highly potent PTP-1B inhibitors, they exhibit only weak cell-based activity, reflective of the poor membrane permeability measured in a Caco-2 assay. Incorporation of the isothiazolidinone moiety into a peptide fragment providing enzyme recognition afforded 362, a PTP-1B inhibitor almost 10-fold more potent than the corresponding difluorophosponate 363.324,325 Chirality was found to be critically important, since the enantiomer 364 and the unsaturated analogue 365 were found to be considerably weaker enzyme inhibitors. However, this series of isothiazolidinone-based inhibitors failed to demonstrate activity in cell-based assays, attributed to poor membrane permeability.322,324,325 Attempts to address this problem by diminishing the peptidic nature of the molecule focused on introducing a benzimidazole moiety as a lipophilic amide isostere designed to maintain an important H-bond with Asp48, a tactic exemplified by 366 and 367.324,325 The sulfonamide NH of both compounds similarly maintains a H-bond to the other oxygen atom of Asp48, and the phenyl ring is important for activity because the methyl analogue is 18-fold less potent. The ortho-F atom in 367 promotes an orthogonal topography for the isothiazolidinone element designed to 3.14.3. Squarates as Phosphate Isosteres. Squaric acid diamides exist in four possible rotamers, and calculations indicate that the E,Z isomer is favored to an extent of 93% at 25 °C (Figure 65), although N,N0 -diphenyl-N,N0 -dimethyldisquaramide behaves differently, since the E,E isomer is more stable because of π-π stacking between the phenyl rings (Figure 66).327 Squaric acid diamides have been modeled as phosphate isosteres in DNA, with electrostatic potential maps indicative of reasonable phosphate mimicry based on significant charge residing on the key oxygen atoms. Squarate oxygen atoms carry charges of -0.47 and -0.51, compared to a charge of-0.84 on each phosphate oxygen atom.328 This analysis provided confidence to prepare a series of thymidine dimers based on the squaryldiamide 368 designed to mimic the natural dinucleotide 369 for incorporation into oligonucleotides.328 By use of thymidine as the base, the squaryldiamide, designated TsqT, was shown to possess a similar structure by CD and UV analysis to the natural analogue, designated TpT. TsqT was shown to bind Mg2þ by 1H NMR and further examined in the context of the hybridization of the oligonucleotide 50 -d(CGCATsqTAGCC)-30 to its complementary natural sequence 50 -(DGGCTAATGCG)-30 . The base pairing ability of the TsqT-containing oligonucleotide was preserved, but the DNA duplex was distorted by the TsqT moiety, detected in the melting temperature Tm of 30.4 °C compared to a Tm of 41.7 °C for the unmodified duplex. Notably, 50 -d(CGCATsqTAGCC)-30 2572 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 65. Conformational isomers of squaric acid diamides. Figure 64. Design of isothiazolidinone-based inhibitors of protein tyrosine phosphatase-1B (PTP-1B) based on topological overlay of two structurally different chemotypes. was stable toward both snake venom phosphodiesterase and alkaline phosphatase.328 Figure 66. Preferred conformation of N,N0 -diphenyl-N,N0 -dimethyldisquaramide. The squaric acid monoamide moiety was evaluated as a phosphate isostere in the context of nucleotides 370 and their cyclic analogues 371 based on the acidity of this element, pKa = 2.3. The cyclic analogue 371 showed ribose puckering in the N conformation similar to cGMP, and although derivatives were probed as antiviral agents, the results were not disclosed.329 A recent attempt to refine phosphate isosterism by this motif probed the introduction of an additional metal coordinating element to a squaryldiamide, examined in a molecule designed to mimic the sugar-nucleotide GDP-mannose (372), a central mediator of prokaryotic and eukaryotic carbohydrate and glycoconjugate biosynthesis, metabolism, and cell signaling.330 The squaryldiamide 373 was designed as a potential inhibitor of the GDP-mannose-dependent mannosyl transferase dolichol phosphate mannose synthase (DPMS) from Trypanosoma brucei, a validated antitrypansosomal target. It was anticipated that the squaryldiamide moiety would coordinate to the catalytic metal in the active site of DPMS while allowing the introduction of an additional proximal polar element capable of coordinating to the metal, explored with a nitro or carboxylic acid substituent, the latter exemplified by 373. However, despite modeling studies supporting the potential for these molecules to bind to the DPMS active site and 1H NMR data indicative of association of the squaryldiamide moiety with Mg2þ, 373 demonstrated only modest inhibition, with residual enzyme activity measured as 64% at 1 mM drug concentration compared to 8.5% for the natural feedback inhibitor GDP at the same concentration. The poor activity was rationalized by considering the two major rotamers associated with the squaryldiamide moiety, both stabilized by intramolecular H-bonds, with one failing to adequately represent the extended conformation frequently adopted by sugar nucleotides.330 3.14.4. HIV-1 Integrase Inhibitors and Phosphate Isosterism. HIV-1 integrase catalyzes the cleavage of the 50 terminal GT dinucleotide from the newly reverse-transcribed viral DNA following infection (Figure 67A) and, after translocating to the cell nucleus, the integration of HIV-1 DNA into the host cell chromosome, the so-called strand transfer step depicted in Figure 67B.331 Successful inhibitors of integrase specifically target the strand transfer step, binding to the active site Mg2þ ions in conjunction with viral DNA and acting as mimics of the transition state intermediate.332 A synopsis of some of the more the successful motifs that have been designed as part of the search for clinically useful HIV integrase inhibitors is collected in Figure 68. While a large family of HIV-1 integrase inhibitors have been disclosed that are based on a wide range of scaffolds, the only 2573 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 67. Topology of the HIV-1 integrase enzyme-substrate complex during the cleavage (A) and strand transfer step (B). Figure 68. Synopsis of HIV-1 integrase-inhibiting motifs. Figure 69. Topological mimicry of the diphosphate moiety of farnesyl pyrophosphate by the maleic acid element found in chaetomellic acids A and B. clinically relevant compounds to emerge to date are the pyrimidinedione raltegravir (374), licensed in the United States in 2007, the quinoline carboxylic acid elvitegravir (375), currently in phase 3 clinical trials, and the pyrido[1,2-a]pyrazine S/GSK1349572 (376) which has recently completed phase 2 studies. These three compounds represent interesting and distinct variants on phosphate transition state mimicry. Most interestingly, 375 is being developed as part of the so-called “quad pill” in which it is coformulated with the nucleoside analogue emtricitabine, the nucleotide analogue tenofovir, and the cytochrome P450 inhibitor cobicistat, the last included to inhibit metabolism of the integrase inhibitor. 3.14.5. Phosphate Isosteres in HIV-1 RNase H and HCV NS5B Inhibitors. The dihydroxypyrimidine 377 is an inhibitor of the RNase H activity associated with HIV-1 reverse transcriptase, with X-ray crystallographic analysis indicating that 377 chelates to the active site metals, presumably acting as a mimic of elements of the transition state during phosphate hydrolysis.333 The dihydroxypyrimidine 378 inhibits HCV NS5B RNAdependent RNA polymerase activity with IC50 = 0.73 μM by a mechanism involving competition with nucleotide incorporation.334 In addition, 378 inhibits pyrophosphate-mediated excision, which is the reverse reaction and is a mechanism by which a nucleotide can be removed from an oligonucleotide. The compound was thus concluded to act as a mimic of 2574 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry pyrophosphate (379), a mechanism analogous to that attributed to foscarnet (380), a simple pyrophosphate analogue marketed for the treatment of several viral infections. PERSPECTIVE Table 50. Pyrophosphate Mimics Explored in the Context of a Series of Nucleoside Triphosphate Analogues Presented to HIV-1 Reverse Transcriptase as Potential Substrates 3.14.6. Pyrophosphate Isosteres in Ras Inhibitors. Ras proteins are membrane-bound GTP-binding proteins involved in signal transduction, and farnesylation of cysteine in a CAAX motif in Ras initiates a sequence of post-translational modifications that ultimately leads to membrane association and activation of the mitotic signaling activity.335 Inhibitors of Ras farnesylation have potential applications in oncology, and several classes of inhibitor have been explored. Chaetomellic acids A (382) and B (383) rely upon structural mimicry of farnesyl pyrophosphate (381) to compete with the natural substrate.336 These compounds inhibit human FTPase with IC50S of 55 and 185 nM, respectively, with the maleic acid element hypothesized to function as a pyrophosphate isostere based on the topological mimicry captured in Figure 69. A molecular modeling exercise established good structural and charge correspondence between a triphosphate moiety 384 and the citrate derivative 385 when configured in the extended conformation, suggesting the potential for isosterism.337,338 The concept was explored in the context of the HIV-1 nucleoside inhibitor d4T with the ester 386 and amide 387 linkers used to connect citrate to the sugar. Ester 386 demonstrated HIV-1 inhibition in cell culture with potency 10-fold weaker than that of d4T and showed weaker activity in thymidine kinase-deficient cells, while the amide 387 was inactive. However, neither compound inhibited HIV-1 reverse transcriptase in a biochemical assay, leading to the conclusion that the ester 386 was cleaved in cell culture to liberate d4T which was phosphorylated by thymidine kinase.337,338 3.14.7. Phosphate Isosteres in HIV-1 Reverse Transcriptase Substrates. The series of pyrophosphate isosteres summarized in Table 50 has been examined in the context of modified nucleotides probed as substrates of HIV-1 reverse transcriptase (RT).339-347 Initial studies focused on phosphoramidates prepared from adenine monophosphate and the natural amino acids aspartate, glutamate, histidine, and proline.340,341 While the glutamate and proline derivatives were found to be poor substrates of HIV-1 RT, the L-Asp (388) and L-His (392) derivatives 2575 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Table 51. Steady State Kinetics for Incorporation of a Series of Natural and Modified Nucleotides by HIV-1 Reverse Transcriptase Vmax Vmax/Km (106 min-1) (pmol/(min U)) Km (μM) dATP 8.39 0.46 18.1 Asp-dAMP (388) 2.63 185.3 0.014 dGTP 28.81 0.54 53.4 Asp-dGMP (389) dTTP 2.14 30.82 168.8 0.53 0.013 58.2 Asp-dTMP (390) 2.33 288.2 0.008 dCTP 5.62 3.74 1.5 Asp-dCMP (391) 0.59 130.8 0.005 His-dAMP (392) 0.33 505.0 0.0007 ILA-dAMP (393) 2.75 204.7 0.013 substrate Figure 70. Shape mimetics of the Mg2þ-bound triphosphate moiety. were processed by the enzyme with the Vmax for Asp just 3-fold lower than that of the natural substrate (data compiled in Table 51). However, the Km value for 388 is substantially higher than that of the natural substrate, reflecting a scenario in which this modified triphosphate is an efficient substrate for the enzyme but possesses only low affinity for the substrate binding site. Extending the Asp-based phosphoramidate concept to the bases guanine, cytosine, and thymine produced substrates with Km values 10- to 15-fold lower than those of the natural triphosphate counterparts, quite remarkable given the significant structural differences.341,342 These results prompted a broader probe of modified substrates from which the cytidine-based malonate derivative 394 was found to be incorporated 1.5-fold more slowly than L-Asp-dAMP while the iminodiacetic acid derivative 395 is a superior substrate with a Vmax/Km just 15-fold lower than that of dATP.343,345 Modification of the amino leaving group of the LHis derivative 392 to an oxygen atom afforded ILA-dAMP (393) for which the Vmax improved almost 10-fold, while the Km was lowered by 2-fold.344 The phosphate 396, an analogue of 388, is an improved substrate with a Km 78-fold higher than that of dATP and a Vmax 1.3-fold slower, affording a Vmax/Km ratio that differs by only 99-fold.346 The guanosine (397), thymine (398), and cytosine (399) analogues of 396 were also probed as bases, with 399 being a poorer substrate than either 397 or 398, while the sulfonic acid analogue 400 was also a poor substrate.346 More radical structural changes to the amino acid moiety have been examined recently, including the isophthalic acid 403, which is incorporated to an extent that is 88% of L-Asp-dAMP, and the aniline analogue 402, which is a poorer substrate.347 Demonstrating the importance of the topological presentation of the two carboxylic acid moieties to the enzyme within this series, the phthalic acid derivative 404 was not recognized by HIV-1 RT as a substrate.347 3.14.8. Phosphate Isosterism in Balanol. Balanol (405) is a fungal metabolite that inhibits both protein kinase C, IC50 = 4 nM, and cAMP-dependent protein kinase, IC50 = 4 nM.348-350 In both cases, 405 is competitive with ATP and an X-ray cocrystal structure with cAMP-dependent protein kinase revealed that balanol occupies the ATP binding site. The benzophenone moiety occupies the triphosphate site, presenting a constellation of polar elements that function as a triphosphate mimetic. However, the benzophenone moiety of 405 is not a precise triphosphate isostere, since the molecule binds in a distinct fashion to the ATP site with the benzamide mimicking adenine and the azepine ring mimicking the ribose moiety of ATP.348-350 3.14.9. Phosphate Shape Mimetics. Shape mimetics of phosphate have been probed for their potential to function as isosteres in a nucleotide sequence where the phosphate moiety was replaced with a less polar isostere.351-353 A simple acetal linkage 407 was examined as a noncharged mimetic of the natural phosphate 406 by incorporation of two of these elements into a 15mer oligonucleotide, both as the 30 ,5linkage shown and as the 20 ,50 -linked isomer.351 The melting temperature, Tm, of hybrids with natural cDNA and RNA sequences was found to vary, with the RNA hybrids more stable than the DNA hybrids. For the 20 ,50 -linked topology, the Tm decreased approximately 0.5 °C per linkage for RNA. The hexafluoroacetone ketal 408 was subsequently conceived based on the notion of optimizing the steric similarity with phosphate, and two of these dinucleotide elements were also incorporated into a 15mer for hybrid stability analysis.352 In this example, the Tm of the hybrid with both RNA and DNA oligonucleotides decreased by 2-2.5 °C compared to the natural oligonucleotides, with the modest level of bioisosterism attributed to reduced hydration of the CF3 group when compared to oxygen.352 Mimetics designed to recapitulate the shape of a nucleoside triphosphate bound to Mg2þ observed in X-ray structures have been probed based on the structural analogy summarized in Figure 70. However, compounds based on this concept, including the adenine triphosphate analogue 409, demonstrated no significant biological activity and the modest 2576 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 71. Binding interactions between inhibitors of poly(ADP-ribose) polymerase-1 and the chicken PARP enzyme. HIV-1 inhibition observed in cell culture with esters derived from d4T and AZT was attributed to hydrolysis to the parent nucleoside.354-356 3.15. Isosteres of Ligand-Water Complexes. Ligandprotein complexes may contain water as a mediator of the interface, and there is potential affinity gain based on an increase in entropy by releasing a bound water molecule.357,358 The strategy of introducing functionality to protein ligands in a fashion designed to displace an interfacial water molecule, in essence creating an isostere of the molecular combination, has been successfully exploited as a means of increasing potency in several drug-target interactions. However, this tactic has not always been effective and the examples described to date suggest that the success of this approach is dependent upon the context, both of the ligand and the protein. 3.15.1. Displacing Water from the Binding Site of HIV-1 Protease. The synthesis of novel HIV-1 protease inhibitors that relied upon replacing the water molecule mediating the interfacial interactions between the flap Ile50/Ile500 NHs and the P2/P20 carbonyl moieties of linear peptidomimetic inhibitors related to 410 represented a pioneering approach to drug design.359-361 A series of cyclic ureas, exemplified by 411, were conceived based on the premise that the urea carbonyl oxygen could effectively replace the water molecule, with additional benefit afforded by conformational preorganization of the inhibitor. Emerging from the early phase of this work, the urea 412 is a potent HIV protease inhibitor, Ki = 0.27 nM, that demonstrates antiviral activity in cell culture, EC90 = 57 nM.359 Another class of HIV-1 protease inhibitor that displaces the flap water is a series of lysine sulfonamide derivatives that are based on classic peptidomimetic inhibitors but modified by the introduction of an additional methylene between the classic hydroxyl transition state mimetic and the alkylene backbone.362 Crystallization of the sulfonamide 413, a potent antiviral in cell culture with an EC50 = 30 nM, with HIV-1 protease revealed that the CH2OH moiety is within H-bonding distance of both catalytic residues Asp25 and Asp250 , but the inclusion of the extra CH2 induces a distortion in the binding mode compared to more conventional peptide-derived inhibitors. As a consequence, the sulfonamide moiety is projected toward the flap residues, displacing the water molecule with both sulfone oxygen atoms accepting H-bonds from the flap Ile50 and Ile500 NHs while the hydroxymethyl moiety is within H-bonding distance of the catalytic aspartate residues.362 3.15.2. Displacing Water in Poly(ADP-ribose) Polymerase-1 (PARP) Inhibitors. Inhibitors of poly(ADP-ribose) polymerase-1 are of potential utility in preventing DNA repair, thereby prolonging the antitumor activity of certain anticancer ther5-Phenyl-2,3,4,6-tetrahydro-1Hapeutic agents.363-365 azepino[5,4,3-cd]indol-1-one is a potent inhibitor of human PARP-1, Ki = 6 nM, that was cocrystallized with chicken PARP to reveal an interfacial water molecule, H2O-52, mediating an 2577 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry PERSPECTIVE Figure 72. Binding interactions between scytalone dehydratase and inhibitors. Table 52. Inhibiton of Human Poly(ADP-ribose) Polymerase-1 by Substituted 3,4-Dihydro[1,4]diazepino[6,7,1-hi]indol-1(2H)-ones interaction between the indole NH and Glu988, as summarized in Figure 71A.363 By inversion of the topology of the indole moiety, a series of 3,4-dihydro[1,4]diazepino[6,7,1-hi]indol1(2H)-ones were designed that provided an opportunity to functionalize C-3 with substituents with the potential to engage Glu988 by displacing H2O-52 (Figure 71B).364 The (E)-carboxaldeoxime 416 satisfied the design criteria and is a potent human PARP-1 inhibitor, Ki = 9.4 nM, an order of magnitude more potent than the unsubstituted parent 414 and several-fold more potent than the hydroxymethyl derivative 415 (data compiled in Table 52). The structure-activity relationships surrounding C- and O-methylation (417-419) supported the design hypothesis that the oxime moiety displaced H2O-52, confirmed by solving the cocrystal structure with (E)-carboxaldeoxime 416 which revealed the oxime OH engaging Glu988 (Figure 72B). However, in the C-6 aryl series 420-423, the effect of introducing the oxime moiety was less visible. 3.15.3. Displacing Water in Scytalone Dehydratase. Scytalone dehydratase is an enzyme in the plant fungal pathogen Magnaporthe grisea that catalyzes two steps in the melanin Table 53. Kinetic Constants for Inhibitors of Scytalone Dehydratase biosynthesis pathway.366 The quinazoline 424 and benzotriazine 427 are potent inhibitors of scytalone dehydratase that were modeled in the enzyme active site as isosteres of a salicylamide derivative cocrystallized with the enzyme (Figure 72A). This exercise recognized the potential to displace the water molecule interfacing between the inhibitor and Tyr50 by introducing a H-bond acceptor to the heterocyclic nucleus, realized with the nitriles 426 and 429 (Table 53). Both compounds were markedly more potent inhibitors of the enzyme than the parent molecules and substantially more potent than the C-H analogues 425 and 428, consistent with the modeling hypothesis. An X-ray cocrystal of 429 with scytalone dehydratase validated the predictions, revealing the interactions depicted in Figure 72B.366 3.15.4. Displacing Water in p38R MAP Kinase Inhibitors. The tactic of replacing the nitrogen atom of the triazine-based p38R MAP kinase inhibitor 430, Ki = 3.7 nM, with C-CN in order to displace a bound water molecule observed in an X-ray structure led to the design of the cyanopyrimidine 431 which, with measured Ki = 0.057 nM, offered a 60-fold enhancement of potency.367 X-ray crystallographic data obtained with a closely analogous compound demonstrated that the cyano moiety engaged the NH of Met109 in a H-bonding interaction, displacing the water molecule interfacing Met109 2578 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry with the triazine N of 430, as anticipated during the design exercise. PERSPECTIVE ’ AUTHOR INFORMATION Corresponding Author *Contact information. Phone: 203-677-6679. Fax: 203-6777884. E-mail: [email protected]. 3.15.5. Displacing Water in Epidermal Growth Factor Receptor Kinase Inhibitors. An attempt to devise inhibitors of the epidermal growth factor receptor (EGFR) kinase inhibitor that displaced an interfacial water molecule proposed to bridge the prototype 432 to Thr766 in a homology model of the kinase was, however, not successful.358,368 Somewhat surprisingly, the C-3 nitrile 433 was found to be almost 3-fold weaker than 432, and ester, amide, carbinol, and carboxylic acid substituents at C-3 were even poorer inhibitors. While this may be a function of inaccuracies associated with the homology model, a detailed analysis of the energetics of the interaction of a series of quinazolines, quinolines, and quinoline nitriles related to 432 and 433 with the EGFR protein suggested an alternative explanation.358 In these modeling studies, the water remained strongly stabilized in the active site in the presence of 432 and the corresponding quinoline analogue, while the water molecule was displaced by the nitrile of 433, as anticipated. A possible explanation recognized the potential for the quinoline analogue of 432 to bind in a fashion that retained the water molecule which was suggested to reorient itself to donate a H-bond to the bromophenyl ring, leading to a preservation of binding energy rather than the anticipated loss in affinity when the H-bonding interaction is lost by exchange of the quinazoline N by a C-H.358 4. SUMMARY This Perspective highlighted a selection of recent approaches to the design of bioisosteres that places an emphasis on practical applications focused on problem solving. The design and application of isosteres have inspired medicinal chemists for almost 80 years, fostering creativity directed toward solving a range of problems in drug design, including understanding and optimizing drug-target interactions and specificity, improving drug permeability, reducing or redirecting metabolism, and avoiding toxicity. As an established and powerful concept in medicinal chemistry, the application of bioisosteres will continue to play an important role in drug discovery, with the anticipation of increased sophistication in the recognition and design of functional mimetics. ’ BIOGRAPHIES Nicholas A. Meanwell received his Ph.D. degree from the University of Sheffield, U.K., with Dr. D. Neville Jones and conducted postdoctoral studies at Wayne State University, MI, in collaboration with Professor Carl R. Johnson. He joined BristolMyers Squibb in 1982 where he is currently Executive Director of Discovery Chemistry with responsibility for the optimization of new therapies for the treatment of viral diseases. His team has pioneered several areas of antiviral drug discovery, including the identification of inhibitors of respiratory syncytial virus fusion peptide 6-helix bundle function and the development of the cyclopropylacylsulfonamide moiety that is widely used in HCV NS3 protease inhibitors, inhibitors of HIV attachment, and inhibitors of HCV NS5A, the last two of which have established clinical proof-of-concept for their respective mechanisms. ’ ACKNOWLEDGMENT This article is based on a short course presented at an ACS ProSpectives conference held in Philadelphia, PA, October 4-6, 2009. I thank Dr. Paul S. Anderson for encouragement to publish this synopsis and my colleagues Drs. Lawrence B. Snyder, John V. Duncia, Dinesh Vyas, Richard A. Hartz, John F. Kadow, Yan Shi, and James E. Sheppeck for sharing some of their insights and for stimulating discussions. I also thank Drs. Naidu Narasimhulu and Dinesh Vyas for critical appraisals of the manuscript. ’ ABBREVIATIONS USED ACE, angiotensin converting enzyme; AMPA, R-amino-3-hydroxyl5-methyl-4-isoxazole propionate; BK, bradykinin; CSD, Cambridge Structural Database; COMT, catechol O-methyl transferase; COX, cycloxygenase; CRF, corticotropin-releasing factor; CTCL, cutaneous T-cell lymphoma; CYP 450, cyctochrome P450; D, deuterium; DAT, dopamine transporter; DFT, density functional theory; DHP, dihydropyridine; DPMS, GDP-mannose-dependent mannosyl transferase dolichol phosphate mannose synthase; EGFR, epidermal growth factor receptor; FAAH, fatty acid amide hydrolase; FPA, fluorescence polarization assay; GABA, γ-aminobutyric acid; GluR, glutamate receptor; GPCR, G-protein-coupled receptor; GSH, glutathione; GSK3, glycogen synthase kinase 3; GST, glutathione transferase; H, hydrogen; HDAC, histone deacetylase; hERG, human ether-a-go-go-related gene; KIE, kinetic isostope effect; KSP, kinesin spindle protein; HCV, hepatitis C virus; HIV, human immunodeficiency virus; HLM, human liver microsomes; HNE, human neutrophil elastase; JAK2, Janus kinase 2; LOX, 5lipoxygenase; LPA, lysophosphatidic acid; MI, CYP 450 metabolic intermediate; MMP, matrix metalloprotease; MPTP, 1-methyl-4phenyl-1,2,3,6-tetrahydropyridine; NET, norepinephrine transporter; NMDA, N-methyl-D-aspartate; NNRTI, non-nucleside reverse transcriptase inhibitor; PCB, protein covalent binding; PDB, Protein Data Bank; PK, pharmacokinetic; PGI2, prostacyclin; PGE2, prostaglandin E2; PTB-1B, protein tyrosine phosphatase 1B; RLM, rat liver microsomes; RSV, respiratory syncytial virus; RT, reverse transcriptase; RXR, retinoid X receptor; SAR, structure-activity relationship; SERT, serotonin transporter; TNFR, tumor necrosis factor R; TRPV1, transient receptor potential vanilloid 1; TACE, 2579 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry tumor necrosis factor R-converting enzyme; VLA-4, very late antigen-4 (CD49d/CD29) ’ REFERENCES (1) Burger, A. Isosterism and bioisosterism in drug design. Prog. Drug Res. 1991, 37, 288–362. (2) Patani, G. A.; LaVoie, E. J. Bioisosterism: a rational approach in drug design. Chem. Rev. 1996, 96, 3147–3176. (3) Langmuir, I. Isomorphism, isosterism and covalence. J. Am. Chem. Soc. 1919, 41, 1543–1559. (4) Erlenmeyer, H.; Berger, E. Studies on the significance of structure of antigens for the production and the specificity of antibodies. Biochem. Z. 1932, 252, 22–36. (5) Erlenmeyer, H.; Berger, E.; Leo, M. Relationship between the structure of antigens and the specificity of antibodies. Helv. Chim. Acta 1933, 16, 733–738. (6) Friedman, H. L. Influence of Isosteric Replacements upon Biological Activity. NAS-NRS Publication No. 206; NAS-NRS: Washington, DC, 1951; Vol. 206, pp 295-358. (7) Thornber, C. W. Isosterism and molecular modification in drug design. Chem. Soc. Rev. 1979, 8, 563–580. (8) Lipinski, C. A. Bioisosterism in drug design. Annu. Rep. Med. Chem. 1986, 21, 283–291. (9) The Practice of Medicinal Chemistry; Wermuth, C. G., Ed.; Academic Press: San Diego, CA, 1996; Chapters 12-16, pp 181-310 (2nd ed., 2003). (10) Olsen, P. H. The use of bioisosteric groups in lead optimization. Curr. Opin. Drug Discovery Dev. 2001, 4, 471–478. (11) Sheridan, R. P. The most common chemical replacements in drug-like compounds. J. Chem. Inf. Comput. Sci. 2002, 42, 103–108. (12) Wermuth, C. G. Similarity in drugs: reflections on analogue design. Drug Discovery Today 2005, 11, 348–354. (13) Lima, L. M.; Barriero, E. J. Bioisosterism: a useful strategy for molecular modification in drug design. Curr. Med. Chem. 2005, 12, 23–49. (14) MacMillan, D. W. C. The advent and development of organocatalysis. Nature 2008, 455, 304–308. (15) El Tayar, N.; van de Waterbeemd, H.; Gryllaki, M.; Testa, B.; Trager, W. F. The lipophilicity of deuterium atoms. A comparison of shakeflask and HPLC methods. Int. J. Pharm. 1984, 19, 271–281. (16) Turowski, M.; Yamakawa, N.; Meller, J.; Kimata, K.; Ikegami, T.; Hosoya, K.; Nobuo Tanaka, N.; Thornton, E. R. Deuterium isotope effects on hydrophobic interactions: the importance of dispersion interactions in the hydrophobic phase. J. Am. Chem. Soc. 2003, 125, 13836–13849. (17) Kimata, K.; Hosoya, K.; Araki, T.; Tanaka, N. Direct chromatographic separation of racemates on the basis of isotopic chirality. Anal. Chem. 1997, 69, 2610–2612. (18) Perrin, C. L.; Ohta, B. K.; Kuperman, J. β-Deuterium isotope effects on amine basicity, “inductive” and stereochemical. J. Am. Chem. Soc. 2003, 125, 15008–15009. (19) Perrin, C. L.; Ohta, B. K.; Kuperman, J.; Liberman, J.; Erdelyi, M. Stereochemistry of β-deuterium isotope effects on amine basicity. J. Am. Chem. Soc. 2005, 127, 9641–9647. (20) Perrin, C. L.; Dong, Y. Nonadditivity of secondary deuterium isotope effects on basicity of triethylamine. J. Am. Chem. Soc. 2008, 130, 11143–11148. (21) Perrin, C. L.; Dong, Y. Secondary deuterium isotope effects on the acidity of carboxylic acids and phenols. J. Am. Chem. Soc. 2007, 129, 4490–4497. (22) Wade, D. Deuterium isotope effects on noncovalent interactions between molecules. Chem.-Biol. Interact. 1999, 117, 191– 217. (23) Schneider, F.; Mattern-Dogru, E.; Hillgenberg, M.; Alken, R.-G. Changed phosphodiesterase selectivity and enhanced in vitro efficacy by selective deuteration of sildenafil. Arzneim.-Forsch. 2007, 57, 293–298. PERSPECTIVE (24) Blake, M. I.; Crespi, H. I.; Katz, J. J. Studies with deuterated drugs. J. Pharm. Sci. 1975, 64, 367–391. (25) Nelson, S. D.; Trager, W. F. The use of deuterium isotope effects to probe the active site properties, mechanism of cytochrome P450-catalyzed reactions, and mechanisms of metabolically dependent toxicity. Drug Metab. Dispos. 2003, 31, 1481–1498. (26) Mutlib, A. E. Application of stable isotope-labeled compounds in metabolism and in metabolism-mediated toxicity studies. Chem. Res. Toxicol. 2008, 21, 1672–1689. (27) Sanderson, K. Big interest in heavy drugs. Nature 2009, 458, 269. (28) Yarnell, A. T. Heavy-hydrogen drugs turn heads, again. Firms seek to improve drug candidates by selective deuterium substitution. Chem. Eng. News 2009, 87, 36–39. (29) Schneider, F.; Hillgenberg, M.; Koytchev, R.; Alken, R.-G. Enhanced plasma concentration by selective deuteration of rofecoxib in rats. Arzneim.-Forsch. 2006, 56, 295–300. (30) Westheimer, F. H. The magnitude of the primary kinetic isotope effect for compounds of hydrogen and deuterium. Chem. Rev. 1961, 61, 265–273. (31) Gant, T. G.; Sarshar, S. Substituted Phenethylamines with Serotonergic and/or Norepinephrinergic Activity. U.S. Patent 7,456, 317, November 25, 2008. (32) Fukuda., T.; Nishida, Y.; Zhou, Q.; Yamamoto, I.; Kondo, S.; Azuma, J. The impact of the CYP2D6 and CYP2C19 genotypes on venlafaxine pharmacokinetics in a Japanese population. Eur. J. Clin. Pharmacol. 2000, 56, 175–180. (33) Auspex Pharmaceuticals. Data release available at http://www. auspexpharma.com/auspex_SD254.html. (34) Tung, R. Novel Benzo-[d][1,3]-dioxol Derivatives. WO 2007/ 016431 A2, February 8, 2007. (35) Concert Pharmaceuticals. Press release on September 14th, 2009, available at http://www.concertpharma.com/ACCPPresentation.htm. (36) Murray, M. Mechanisms of inhibitory and regulatory effects of methylenedioxyphenyl compounds on cytochrome P450-dependent drug oxidation. Curr. Drug Metab. 2000, 1, 67–84. (37) Bertelsen, K. M.; Venkatakrishnan, K.; von Moltke, L. L.; Obach, R. S.; Greenblatt, D. J. Apparent mechanism-based inhibition of human CYP 2D6 in vitro by paroxetine: comparison with fluoxetine and quinidine. Drug Metab. Dispos. 2003, 31, 289–293. (38) Mutlib, A. E.; Gerson, R. J.; Meunier, P. C.; Haley, P. J.; Chen, H.; Gan, L. S.; Davies, M. H.; Gemzik, B.; Christ, D. D.; Krahn, D. F.; Markwalder, J. A.; Seitz, S. P.; Robertson, R. T.; Miwa, G. T. The species-dependent metabolism of efavirenz produces a nephrotoxic glutathione conjugate in rats. Toxicol. Appl. Pharmacol. 2000, 169, 102–113. (39) Maltais, F.; Jung, Y. C.; Chen, M.; Tanoury, J.; Perni, R. B.; Mani, N.; Laitinen, L.; Huang, H.; Liao, S.; Gao, H.; Tsao, H.; Block, E.; Ma, C.; Shawgo, R. S.; Town, C.; Brummel, C. L.; Howe, D.; Pazhanisamy, S.; Raybuck, S.; Namchuk, M.; Bennani, Y. L. In vitro and in vivo isotope effects with hepatitis C protease inhibitors: enhanced plasma exposure of deuterated telaprevir versus telaprevir in rats. J. Med. Chem. 2009, 52, 7993–8001. (40) Begue, J.-P.; Bonnet-Delpon, D. Bioorganic and Medicinal Chemistry of Fluorine; John Wiley & Sons: Hoboken, NJ, 2008. (41) B€ ohm, H.-J.; Banner, D.; Bendels, S.; Kansy, M.; Kuhn, B.; M€uller, K.; Obst-Sander, U.; Stahl, M. Fluorine in medicinal chemistry. ChemBioChem 2004, 5, 637–643. (42) M€uller, K.; Faeh, C.; Diederich, F. Fluorine in pharmaceuticals: looking beyond intuition. Science 2007, 317, 1881–1886. (43) Hagman, W. K. The many roles for fluorine in medicinal chemistry. J. Med. Chem. 2008, 51, 4359–4369. (44) Purser, S.; Moore, P. R.; Swallow, S.; Gouverneur, V. Fluorine in medicinal chemistry. Chem. Soc. Rev. 2008, 37, 320–330. (45) Shah, P.; Westwell, A. D. The role of fluorine in medicinal chemistry. J. Enzyme Inhib. Med. Chem. 2007, 22, 527–540. (46) O’Hagan, D. Understanding organofluorine chemistry. An introduction to the C-F bond. Chem. Soc. Rev. 2008, 37, 308–319. 2580 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry (47) Goncharov, N. V.; Richard O. Jenkins, R. O.; Radilov, A. S. Toxicology of fluoroacetate: a review, with possible directions for therapy research. J. Appl. Toxicol. 2006, 26, 148–161. (48) Okuda, H.; Ogura, K.; Kato, A.; Takubo, H.; Watabe, T. A possible mechanism of eighteen patient deaths caused by interactions of sorivudine, a new antiviral drug, with oral 5-fluorouracil prodrugs. J. Pharmacol. Exp. Ther. 1998, 287, 791–799. (49) Clader., J. W. The discovery of ezetimibe: a view from outside the receptor. J. Med. Chem. 2004, 41, 1–9. (50) Penning, T. D.; Talley, J. J.; Bertenshaw, S. R.; Carter, J. S.; Collins, P. W.; Docter, S.; Graneto, M. J.; Lee, L. F.; Malecha, J. W.; Miyashiro, J. M.; Rogers, R. S.; Rogier, D. J.; Yu, S. S.; Anderson, G. D.; Burton, E. G.; Cogburn, J. N.; Gregory, S. A.; Koboldt, C. M.; Perkins, W. E.; Seibert, K.; Veenhuizen, A. W.; Zhang, Y. Y.; Isakson, P. C. Synthesis and biological evaluation of the 1,5-diarylpyrazole class of cyclooxygenase-2 inhibitors: identification of 4-[5-(4-methylphenyl)3-(trifluoromethyl)-1H-pyrazol-1-yl]benzenesulfonamide (SC-58635, celecoxib). J. Med. Chem. 1997, 40, 1347–1365. (51) Diana, G. D.; Rudewicz, P.; Pevear, D. C.; Nitz, T. J.; Aldous, S. C.; Aldous, D. J.; Robinson, D. T.; Draper, T.; Dutko, F. J.; Aldi, C.; Gendron, G.; Oglesby, R. C.; Volkots, D. L.; Reurnan, M.; Bailey, T. R.; Czerniak, R.; Block, T.; Roland, R.; Oppermand, J. Picornavirus inhibitors: trifluoromethyl substitution provides a global protective effect against hepatic metabolism. J. Med. Chem. 1996, 38 (1355-1371), 1355. (52) Park, R.; Kitteringham, N. R. Effects of fluorine substitution on drug metabolism: pharmacological and toxicological implications. Drug Metab. Rev. 1994, 26, 605–643. (53) Swaminathan, S.; Siddiqui, A. U.; Pinkerton, N. G.; Wilson, W. K.; Schroepfer, G. J. Inhibitors of sterol synthesis: 3β-hydroxy25,26,26,26,27,27-heptafluoro-5R-cholestan-15-one, an analog of a potent hypocholesterolemic agent in which its major metabolism is blocked. Biochem. Biophys. Res. Commun. 1994, 201, 168–173. (54) Banni, K; Tom, T.; Oba, T.; Tanaka, T.; Okamura, N.; Watanabe, K.; Hazato, A.; Kurozumi, S. Synthesis of chemically stable prostacyclin analogs. Tetrahedron 1983, 39, 3807–3819. (55) Rose, W. C.; Marathe, P. H.; Jang, G. R.; Monticello, T. M.; Balasubramanian, B. N.; Long, B.; Fairchild, C. R.; Wall, M. E.; Wani, M. C. Novel fluoro-substituted camptothecins: in vivo antitumor activity, reduced gastrointestinal toxicity and pharmacokinetic characterization. Cancer Chemother. Pharmacol. 2006, 58, 73–85. (56) Traschel, D.; Hadorn, M.; Baumberger, F. Synthesis of fluoro analogues of 3,4-(methylenedioxy)amphetamine (MDA) and its derivatives. Chem. Biodiversity 2006, 3, 326–336. (57) Cox, C. D.; Coleman, P. J.; Breslin, M. J.; Whitman, D. B.; Garbaccio, R. M.; Fraley, M. E.; Buser, C. A.; Walsh, E. S.; Hamilton, K.; Schaber, M. D.; Lobell, R. B.; Tao, W.; Davide, J. P.; Diehl, R. E.; Abrams, M. T.; South, V. J.; Huber, H. E.; Torrent, M.; Prueksaritanont, T.; Li, C.; Slaughter, D. E.; Mahan, E.; Fernandez-Metzler, C.; Yan, Y.; Kuo, L. C.; Kohl, N. E.; Hartman, G. D. Kinesin spindle protein (KSP) inhibitors. 9. Discovery of (2S)-4-(2,5-difluorophenyl)-N-[(3R,4S)-3-fluoro-1methylpiperidin-4-yl]-2-(hydroxymethyl)-N-methyl-2-phenyl-2,5-dihydro-1H-pyrrole-1-carboxamide (MK-0731) for the treatment of taxanerefractory cancer. J. Med. Chem. 2008, 51, 4239–4252. (58) Cerny, M. A.; Hanzlik, R. P. Cyclopropylamine inactivation of cytochromes P450: role of metabolic intermediate complexes. Arch. Biochem. Biophys. 2005, 436, 265–275. (59) O’Hagan, D.; Rzepa, H. S. Some influences of fluorine in bioorganic chemistry. Chem. Commun. 1997, 645–652. (60) Briggs, C. R. S.; O’Hagan, D; Howard, J. A. K.; Yufit, D. S. The C-F bond as a tool in the conformational control of amides. J. Fluorine Chem. 2003, 119, 9–13. (61) Banks, J. W.; Batsanov, A. S.; Howard, J. A. K.; O’Hagan, D.; Rzepa, H. S.; Martin-Santamaria, S. The preferred conformation of R-fluoroamides. J. Chem. Soc., Perkin Trans. 2 1995, 2409–2411. (62) O’Hagan, D.; Bilton, C.; Howard, J. A. K.; Knight, L.; Tozer, D. J. The preferred conformation of N-β-fluoroethylamides. Observation of the fluorine amide gauche effect. J. Chem. Soc., Perkin Trans. 2 2001, 605–607. PERSPECTIVE (63) Buissonneaud, D. Y.; van Mourik, T.; O’Hagan, D. A DFT study on the origin of the fluorine gauche effect in substituted fluoroethanes. Tetrahedron 2010, 66, 2196–2202. (64) Hyla-Kryspin, I.; Grimme, S.; Hruschka, S.; Haufe, G. Conformational preferences and basicities of monofluorinated cyclopropyl amines in comparison to cyclopropylamine and 2-fluoroethylamine. Org. Biomol. Chem. 2008, 6, 4167–4175. (65) Abraham, R. J.; Chambers, E. J.; Thomas, W. A. Conformational analysis. Part 22. An NMR and theoretical investigation of the gauche effect in fluoroethanols. J. Chem. Soc., Perkin Trans. 2 1994, 949–955. (66) Briggs, C. R. S.; Allen, M. J.; O’Hagan, D.; Tozer, D. J.; Slawin, A. M. Z.; Goeta, A. E.; Howard, J. A. K. The observation of a large gauche preference when 2-fluoroethylamine and 2-fluoroethanol become protonated. Org. Biomol. Chem. 2004, 2, 732–740. (67) Deniau, G.; Slawin, A. M. Z.; Lebl, T.; Chorki, F.; Issberner, J. P.; van Mourik, T.; Heygate, J. M.; Lambert, J. J.; Etherington, L.-A.; Sillar, K. T.; O’Hagan, D. Synthesis, conformation and biological evaluation of the enantiomers of 3-fluoro-γ-aminobutyric acid ((R)and (S)-3F-GABA): an analogue of the neurotransmitter GABA. ChemBioChem 2007, 8, 2265–2274. (68) Borden, W. T. Effects of electron donation into C-F σ* orbitals: explanations, predictions and experimental tests. Chem. Commun. 1998, 1919–1925. (69) Tozer, D. J. The conformation and internal rotational barrier of benzyl fluoride. Chem. Phys. Lett. 1999, 308, 160–164. (70) Bitencourt, M.; Freitas, M. P.; Rittner, R. Conformational and stereoelectronic investigation in 1,2-difluoropropane: the gauche effect. J. Mol. Struct. 2007, 840, 133–136. (71) Sch€uler, M.; O’Hagan, D.; Slawin, A. M. Z. The vicinal F-C-C-F moiety as a tool for influencing peptide conformation. Chem. Commun. 2005, 4324–4326. (72) Hunter, L.; Kirsch, P.; Hamilton, J. T. G.; O’Hagan, D. The multi-vicinal fluoroalkane motif: an examination of 2,3,4,5-tetrafluorohexane stereoisomers. Org. Biomol. Chem. 2008, 6, 3105–3108. (73) Winkler, M.; Moraux, T.; Khairy, H. A.; Scott, R. H.; Slawin, A. M. Z.; O’Hagan, D. Synthesis and vanilloid receptor (TRPV1) activity of the enantiomers of R-fluorinated capsaicin. ChemBioChem 2009, 10, 823–828. (74) Domagala, J. M.; Hanna, L. D.; Heifetz, C. L.; Hutt, M. P.; Mich, T. F.; Sanchez, J. P.; Solomon, M. New structure-activity relationships of the quinolone antibacterials using the target enzyme. The development and application of a DNA gyrase assay. J. Med. Chem. 1986, 29, 394–404. (75) Barbachyn, M. R.; Ford, C. W. Oxazolidinone structure-activity relationships leading to linezolid. Angew. Chem., Int. Ed. 2003, 42, 2010–2023. (76) Meanwell, N. A.; Wallace, O. B.; Fang, H.; Wang, H.; Deshpande, M.; Wang, T.; Yin, Z.; Zhang, Z.; Pearce, B. C.; James, J.; Yeung, K.-S.; Qiu, Z.; Wright, J. J. K.; Yang, Z.; Zadjura, L.; Tweedie, D. L.; Yeola, S.; Zhao, F.; Ranadive, S.; Robinson, B. A.; Gong, Y.-F.; Wang, H.-G. H.; Blair, W. S.; Shi, P.-Y.; Colonno, R. J.; Lin, P.-f. Inhibitors of HIV-1 attachment. Part 2: An initial survey of indole substitution patterns. Bioorg. Med. Chem. Lett. 2009, 19, 1977–1981. (77) Pinto, D. J. P.; Orwat, M. J.; Wang, S.; Fevig, J. M.; Quan, M. L.; Amparo, E.; Cacciola, J.; Rossi, K. A.; Alexander, R. S.; Smallwood, A. M.; Luettgen, J. M.; Liang, L.; Aungst, B. J.; Wright, M. R.; Knabb, R. M.; Wong, P. C.; Wexler, R. R.; Lam, P. Y. S. Discovery of 1-[3-(aminomethyl)phenyl]-N-[3-fluoro-20 -(methylsulfonyl)-[1,10 -biphenyl]-4-yl]3-(trifluoromethyl)-1H-pyrazole-5-carboxamide (DPC423), a highly potent, selective, and orally bioavailable inhibitor of blood coagulation factor Xa. J. Med. Chem. 2001, 44, 566–578. (78) Quan, M. L.; Lam, P. Y. S.; Qi Han, Q.; Pinto, D. J. P.; He, M. Y.; Li, R.; Ellis, C. D.; Clark, C. G.; Teleha, C. A.; Sun, J.-H.; Alexander, R. S.; Bai, S.; Luettgen, J. M.; Knabb, R. M.; Wong, P. C.; Wexler, R. R. Discovery of 1-(30 -aminobenzisoxazol-50 -yl)-3-trifluoromethyl-N-[2fluoro-4-[(20 -dimethylaminomethyl)imidazol-1-yl]phenyl]-1H-pyrazole5-carboxyamide hydrochloride (razaxaban), a highly potent, selective, 2581 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry and orally bioavailable factor Xa inhibitor. J. Med. Chem. 2005, 48, 1729– 1744. (79) Sehon, C. A.; Wang, G. Z.; Viet, A. Q.; Goodman, K. B.; Dowdell, S. E.; Elkins, P. A.; Semus, S. F.; Evans, C.; Jolivette, L. J.; Kirkpatrick, R. B.; Dul, E.; Khandekar, S. S.; Yi, T.; Wright, L. L.; Smith, G. K.; Behm, D. J.; Bentley, R.; Doe, C. P.; Hu, E.; Lee, D. Potent, selective and orally bioavailable dihydropyrimidine inhibitors of rho kinase (ROCK1) as potential therapeutic agents for cardiovascular diseases. J. Med. Chem. 2008, 51, 6631–6634. (80) Dai, Y.; Hartandi, K.; Ji, Z.; Ahmed, A. A.; Albert, D. H.; Bauch, J. L.; Bouska, J. J.; Bousquet, P. F.; Cunha, G. A.; Glaser, K. B.; Harris, C. M.; Hickman, D.; Guo, J.; Li, J.; Marcotte, P. A.; Marsh, K. C.; Moskey, M. D.; Martin, R. L.; Olson, A. M.; Osterling, D. J.; Pease, L. L.; Soni, N. B.; Stewart, K. D.; Stoll, V. S.; Tapang, P.; Reuter, D. R.; Davidsen, S. K.; Michaelides, M. R. Discovery of N-(4-(3-amino-1Hindazol-4-yl)phenyl)-N0 -(2-fluoro-5-methylphenyl)urea (ABT-869), a 3-aminoindazole-based orally active multitargeted receptor tyrosine kinase inhibitor. J. Med. Chem. 2007, 50, 1584–1597. (81) Marsham, P. R.; Wardleworth, J. M.; Boyle, F. T.; Hennequin, L. F.; Kimbell, R.; Brown, M.; Jackman, A. L. Design and synthesis of potent non-polyglutamatable quinazoline antifolate thymidylate synthase inhibitors. J. Med. Chem. 1999, 42, 3809–3820. (82) Tran, C.; Ouk, S.; Clegg, N. J.; Chen, Y.; Watson, P. A.; Arora, V.; Wongvipat, J.; Smith-Jones, P. M.; Yoo, D.; Kwon, A.; Wasielewska, T.; Welsbie, D.; Chen, C.; Higano, C. S.; Beer, T. M.; Hung, D. T.; Scher, H. I.; Jung, M. E.; Sawyers, C. L. Development of a second-generation antiandrogen for treatment of advanced prostate cancer. Science 2009, 324, 787–790. (83) Jung, M. E.; Ouk, S.; Yoo, D.; Sawyers, C. L.; Chen, C.; Tran, C.; Wongvipat, J. Structure-activity relationship for thiohydantoin androgen receptor antagonists for castration-resistant prostate cancer (CRPC). J. Med. Chem. 2010, 53, 2779–2796. (84) Skuballa, W.; Schillinger, E.; St€urzebecher, C.-St.; Vorbr€uggen, H. Synthesis of a new chemically and metabolically stable prostacyclin analogue with high and long-lasting oral activity. J. Med. Chem. 1986, 29, 313–315. (85) Kim, J.-J. P.; Battaile, K. P. Burning fat: the structural basis of fatty acid β-oxidation. Curr. Opin. Struct. Biol. 2002, 12, 721–728. (86) Meanwell, N. A.; Romine, J. L.; Seiler, S. M. Non-prostanoid prostacyclin mimetics. Drugs Future 1994, 19, 361–385. (87) Meanwell, N. A.; Rosenfeld, M. J.; Trehan, A. K.; Wright, J. J. K.; Brassard, C. L.; Buchanan, J. O.; Federici, M. E.; Fleming, J. S.; Gamberdella, M.; Zavoico, G. B.; Seiler, S. M. Nonprostanoid prostacyclin mimetics. 2. 4,5-Diphenyloxazole derivatives. J. Med. Chem. 1992, 35, 3483–3497. (88) Hehre, W. J.; Radom, L.; Pople, J. A. Molecular orbital theory of the electronic structure of organic compounds. XII. Conformations, stabilities, and charge distributions in monosubstituted benzenes. J. Am. Chem. Soc. 1972, 94, 1496–1504. (89) Anderson, G. M., III; Kollman, P. A.; Domelsmith, L. N.; Houk, K. N. Methoxy group nonplanarity in o-dimethoxybenzenes. Simple predictive models for conformations and rotational barriers in alkoxyaromatics. J. Am. Chem. Soc. 1979, 101, 2344–2352. (90) Hummel, W.; Huml, K.; B€urgi, H.-B. Conformational flexibility of the methoxyphenyl group studies by statistical analysis of crystal structure data. Helv. Chim. Acta 1988, 71, 1291–1302. (91) Brameld, K. A.; Kuhn, B.; Reuter, D. C.; Stahl, M. Small molecule conformational preferences derived from crystal structure data. A medicinal chemistry focused analysis. J. Chem. Inf. Model. 2008, 48, 1–24. (92) Bryan, R. F.; Freyberg, D. P. Crystal structures of R-trans- and p-methoxy-cinnamic acids and their relation to thermal mesomorphism. J. Chem. Soc, Perkin Trans. 2 1975, 1835–1840. (93) Johnson, F. Allylic strain in six-membered rings. Chem. Rev. 1968, 68, 375–413. (94) Juteau, H.; Gareau, Y.; Labelle, M.; Sturino, C. F.; Sawyer, N.; Tremblay, N.; Lamontagne, S.; Carriere, M.-C.; Denis, D.; Metters, K. M. Structure-activity relationship of cinnamic acylsulfonamide PERSPECTIVE analogues on the human EP3 prostanoid receptor. Bioorg. Med. Chem. 2001, 9, 1977–1984. (95) Bains, W.; Tacke, R. Silicon chemistry as a novel source of chemical diversity in drug design. Curr. Opin. Drug Discovery Dev. 2003, 6, 526–543. (96) Showell, G. A.; Mills, J. S. Chemistry challenges in lead optimization: silicon isosteres in drug discovery. Drug Discovery Today 2003, 8, 551–556. (97) Mills, J. S.; Showell, G. A. Exploitation of silicon medicinal chemistry in drug discovery. Expert Opin. Invest. Drugs 2004, 13, 1149–1157. (98) Franz, A. K. The synthesis of biologically active organosilicon small molecules. Curr. Opin. Drug Discovery Dev. 2007, 10, 654–671. (99) Barnes, M. J.; Conroy, R.; Miller, D. J.; Mills, J. S.; Montana, J. G.; Pooni, P. K.; Showell, G. A.; Walsh, L. M.; Warneck, J. B. H. Trimethylsilylpyrazoles as novel inhibitors of p38 MAP kinase: a new use of silicon bioisosteres in medicinal chemistry. Bioorg. Med. Chem. Lett. 2007, 17, 354–357. (100) Showell, G. A.; Barnes, M. J.; Daiss, J. O.; Mills, J. S.; Montana, J. G.; Tacke, R.; Warnecka, J. B. H. (R)-Sila-venlafaxine: a selective noradrenaline reuptake inhibitor for the treatment of emesis. Bioorg. Med. Chem. Lett. 2006, 16, 2555–2558. (101) Daiss, J. O.; Burschka, C.; Mills, J. S.; Montana, J. G.; Showell, G. A.; Warneck, J. B. H.; Tacke, R. Sila-venlafaxine, a sila-analogue of the serotonin/noradrenaline reuptake inhibitor venlafaxine: synthesis, crystal structure analysis, and pharmacological characterization. Organometallics 2006, 25, 1188–1198. (102) Daiss, J. O.; Burschka, C.; Mills, J. S.; Montana, J. G.; Showell, G. A.; Warneck, J. B. H.; Tacke, R. Synthesis, crystal structure analysis, and pharmacological characterization of desmethoxy-sila-venlafaxine, a derivative of the serotonin/noradrenaline reuptake inhibitor sila-venlafaxine. J. Organomet. Chem. 2006, 691, 3589–3595. (103) Tacke, R.; Popp, F.; M€uller, B.; Theis, B.; Burschka, C.; Hamacher, A.; Kassack, M. U.; Schepmann, D.; W€unsch, B.; Jurva, U.; Wellner, E. Sila-haloperidol, a silicon analogue of the dopamine (D2) receptor antagonist haloperidol: synthesis, pharmacological properties, and metabolic fate. ChemMedChem 2008, 3, 152–164. (104) Subramanyam, B.; Woolf, T.; Castagnoli, N., Jr. Studies on the in-vitro conversion of haloperidol to a potentially neurotoxic pyridinium metabolite. Chem. Res. Toxicol. 1991, 4, 123–128. (105) Johansson, T.; Weidolf, L.; Popp, F.; Tacke, R.; Jurva, U. In vitro metabolism of haloperidol and sila-haloperidol: new metabolic pathways resulting from carbon/silicon exchange. Drug Metab. Dispos. 2010, 38, 73–83. (106) Tacke, R.; Nguyen, B.; Burschka, C.; Lippert, W. P.; Hamacher, A.; Urban, C.; Kassack, M. U. Sila-trifluperidol, a silicon analogue of the dopamine (D2) receptor antagonist trifluperidol: synthesis and pharmacological characterization. Organometallics 2010, 29, 1652–1660. (107) Lippert, W. P.; Burschka, C.; G€otz, K.; Kaupp, M.; Ivanova, D.; Gaudon, C.; Sato, Y.; Antony, P.; Rochel, N.; Moras, D.; Gronemeyer, H.; Tacke, R. Silicon analogues of the RXR-selective retinoid agonist SR11237 (BMS649): chemistry and biology. ChemMedChem 2009, 4, 1143–1152. (108) Tacke, R.; M€uller, V.; B€uttner, M. W.; Lippert, W. P.; Bertermann, R.; Daiss, J. O.; Khanwalkar, H.; Furst, A.; Gaudon, C.; Gronemeyer, H. Synthesis and pharmacological characterization of disila-AM80 (disilatamibarotene) and disila-AM580, silicon analogues of the RARR-selective retinoid agonists AM80 (tamibarotene) and AM580. ChemMedChem 2009, 4, 1797–1802. (109) Sieburth, S. McN.; Chen, C.-A. Silanediol protease inhibitors: from conception to validation. Eur. J. Org. Chem. 2006, 311–322. (110) Chen, C.-A.; Sieburth, S. McN.; Glekas, A.; Hewitt, G. W.; Trainor, G. L.; Erickson-Viitanen, S.; Garber, S. S.; Cordova, B.; Jeffry, S.; Klabe, R. M. Drug design with a new transition state analog of the hydrated carbonyl: silicon-based inhibitors of the HIV protease. Chem. Biol. 2001, 8, 1161–1166. (111) Kim, J.; Sieburth, S. McN. Silanediol peptidomimetics. Evaluation of four diastereomeric ACE inhibitors. Bioorg. Med. Chem. Lett. 2004, 14, 2853–2856. 2582 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry (112) Kim, J.; Glekas, A.; Sieburth, S. McN. Silanediol-based inhibitor of thermolysin. Bioorg. Med. Chem. Lett. 2002, 12, 3625–3627. (113) Juers, D. H.; Kim, J.; Matthews, B. W.; Sieburth, S. McN. Structural analysis of silanediols as transition-state-analogue inhibitors of the benchmark metalloprotease thermolysin. Biochemistry 2005, 44, 16524–16528. (114) Meanwell, N. A.; Krystal, M. Respiratory syncytial virus: the discovery and optimization of orally bioavailable fusion inhibitors. Drugs Future 2007, 32, 441–455. (115) Yu, K.-L.; Sin, N.; Civiello, R. L.; Wang, X. A.; Combrink, K. D.; Gulgeze, H. B.; Venables, B. L.; Wright, J. J. K.; Dalterio, R. A.; Zadjura, L.; Marino, A.; Dando, S.; D’Arienzo, C.; Kadow, K. F.; Cianci, C. W.; Li, Z.; Clarke, J.; Genovesi, E. V.; Medina, I.; Lamb, L.; Colonno, R. J.; Yang, Z.; Krystal, M.; Meanwell, N.A. Respiratory syncytial virus fusion inhibitors. Part 4: Optimization for oral bioavailability. Bioorg. Med. Chem. Lett. 2007, 17, 895–901. (116) Barrow, J. C.; Rittle, K. E.; Reger, T. S.; Yang, Z.-Q.; Bondiskey, P.; McGaughey, G. B.; Bock, M. G.; Hartman, G. D.; Tang, C.; Ballard, J.; Kuo, Y.; Prueksaritanont, T.; Nuss, C. E.; Doran, S. M.; Fox, S. V.; Garson, S. L.; Kraus, R. L.; Li, Y.; Marino, M. J.; Graufelds, V. K.; Uebele, V. N.; Renger, J. J. Discovery of 4,4-disubstituted quinazolin-2-ones as T-type calcium channel antagonists. ACS Med. Chem. Lett. 2010, 1, 75–79. (117) Miller, D. C.; Klutea, W.; Calabresea, A.; Brown, A. D. Optimising metabolic stability in lipophilic chemical space: the identification of a metabolically stable pyrazolopyrimidine CRF-1 receptor antagonist. Bioorg. Med. Chem. Lett. 2009, 19, 6144–6147. (118) Wuitschik, G.; Rogers-Evans, M.; M€uller, K.; Fischer, H.; Wagner, B.; Schuler, F.; Polonchuk, L.; Carreira, E. M. Oxetanes as promising modules in drug discovery. Angew Chem., Int. Ed. 2006, 45, 7736–7739. (119) Wuitschik, G.; Carreira, E. M.; Wagner, B.; Fischer, H.; Parrilla, I.; Schuler, F.; Rogers-Evans, M.; M€uller, K. Oxetanes in drug discovery: structural and synthetic insights. J. Med. Chem. 2010, 53, 3227–3246. (120) Burkhard, J. A.; Wuitschik, G.; Rogers-Evans, M.; M€uller, K.; Carreira, E. M. Oxetanes as versatile elements in drug discovery and synthesis. Angew. Chem., Int. Ed. 2010, 49, 9052–9067. (121) For example, cLogP values calculated using the chemical properties function of ChemDraw Ultra, version 9, are as follows: tetrahydro-2H-pyran, 0.96; 4,4-dimethyltetrahydro-2H-pyran, 1.99; 6-oxaspiro[2.5]octane (the cyclopropyl analogue), 1.27; 2,7-dioxaspiro[3.5]nonane (the oxetane homologue), -0.57. (122) Tanaka, H.; Shishido, Y. Synthesis of aromatic compounds containing a 1,1-dialkyl-2-trifluoromethyl group, a bioisostere of the tertalkyl moiety. Bioorg. Med. Chem. Lett. 2007, 17, 6079–6085. (123) Leroux, F. Atropisomerism, biphenyls, and fluorine: a comparison of rotational barriers and twist angles. ChemBioChem 2004, 5, 644–649. (124) Jagodzinska, M.; Huguenot, F.; Candiani, G.; Zanda, M. Assessing the bioisosterism of the trifluoromethyl group with a protease probe. ChemMedChem 2009, 4, 49–51. (125) Kitas, E. A.; Galley, G.; Jakob-Roetne, R.; Flohr, A.; Wostl, W.; Mauser, H.; Alker, A. M.; Czech, C.; Ozmen, L.; David-Pierson, P.; Reinhardt., D.; Jacobsen, H. Substituted 2-oxo-azepane derivatives are potent, orally active γ-secretase inhibitors. Bioorg. Med. Chem. Lett. 2008, 18, 304–308. (126) Wang, T.; Yin, Z.; Zhang, Z.; Bender, J. A.; Yang, Z.; Johnson, G.; Yang, Z.; Zadjura, L. M.; D’Arienzo, C. J.; DiGiugno Parker, D.; Gesenberg, C.; Yamanaka, G. A.; Gong, Y.-F.; Ho, H.-T.; Fang, H.; Zhou, N.; McAuliffe, B. V.; Eggers, B. J.; Fan, L.; Nowicka-Sans, B.; Dicker, I. B.; Gao, Q.; Colonno, R. J.; Lin, P.-F.; Meanwell, N. A.; Kadow, J. F. Inhibitors of human immunodeficiency virus type 1 (HIV-1) attachment. 5. An evolution from indole to azaindoles leading to the discovery of 1-(4-benzoylpiperazin-1-yl)-2-(4,7-dimethoxy-1H-pyrrolo[2,3-c]pyridin-3-yl)ethane-1,2-dione (BMS-488043), a drug candidate that demonstrates antiviral activity in HIV-1-infected subjects. J. Med. Chem. 2009, 52, 7778–7787. (127) Hartz, R. A.; Ahuja, V. T.; Zhuo, X.; Mattson, R. J.; Denhart, D. J.; Deskus, J. A.; Vrudhula, V. M.; Pan, S.; Ditta, J. L.; Shu, Y.-Z.; PERSPECTIVE Grace, J. E.; Lentz, K. A.; Lelas, S.; Li, Y.-W.; Molski, T. F.; Krishnananthan, S.; Wong, H.; Qian-Cutrone, J.; Schartman, R.; Denton, R.; Lodge, N. J.; Zaczek, R.; Macor, J. E.; Bronson, J. J. A strategy to minimize reactive metabolite formation: discovery of (S)-4-(1-cyclopropyl-2-methoxyethyl)-6-[6-(difluoromethoxy)-2,5-dimethylpyridin-3-ylamino]-5oxo-4,5-dihydropyrazine-2-carbonitrile as a potent, orally bioavailable corticotropin-releasing factor-1 receptor antagonist. J. Med. Chem. 2009, 52, 7653–7658. (128) Hartz, R. A.; Ahuja, V. T.; Schmitz, W. D.; Molski, T. F.; Mattson, G. K.; Lodge, N. J.; Bronson, J. J.; Macor, J. E. Synthesis and structure-activity relationships of N3-pyridylpyrazinones as corticotropin-releasing factor-1 (CRF1) receptor antagonists. Bioorg. Med. Chem. Lett. 2010, 20, 1890–1894. (129) Zhuo, X.; Hartz, R. A.; Bronson, J. J.; Wong, H.; Ahuja, V. T.; Vrudhula, V. M.; Leet, J. E.; Huang, S.; Macor, J. E.; Shu, Y.-Z. Comparative biotransformation of pyrazinone-containing corticotropinreleasing factor receptor-1 antagonists: minimizing the reactive metabolite formation. Drug Metab. Dispos. 2010, 38, 5–15. (130) Kalgutkar, A. S.; Griffith, D. A.; Ryder, T.; Sun, H.; Miao, Z.; Bauman, J. N.; Didiuk, M. T.; Frederick, K. S.; Zhao, S. X.; Prakash, C.; Soglia, J. R.; Bagley, S. W.; Bechle, B. M.; Kelley, R. M.; Dirico, K.; Zawistoski, M.; Li, J.; Oliver, R.; Guzman-Perez, A.; Liu, K. K. C.; Walker, D. P.; Benbow, J. W.; Morris, J. Discovery tactics to mitigate toxicity risks due to reactive metabolite formation with 2-(2-hydroxyaryl)-5-(trifluoromethyl)pyrido[4,3-d]pyrimidin-4(3H)-one derivatives, potent calcium-sensing receptor antagonists and clinical candidate(s) for the treatment of osteoporosis. Chem. Res. Toxicol. 2010, 23, 1115– 1126. (131) Southers, J. A.; Bauman, J. N.; Price, D. A.; Humphries, P. S.; Balan, G.; Sagal, J. F.; Maurer, T. S.; Zhang, Y.; Oliver, R.; Herr, M.; Healy, D. R.; Li, M.; Kapinos, B.; Fate, G. D.; Riccardi, K. A.; Paralkar, V. M.; Brown, T. A.; Kalgutkar, A. S. Metabolism-guided design of shortacting calcium-sensing receptor antagonists. ACS Med. Chem. Lett. 2010, 1, 219–223. (132) Samuel, K.; Yin, W.; Stearns, R. A.; Tang, Y. S.; Chaudhary, A. G.; Jewell, J. P.; Lanza, T., Jr.; Lin, L. S.; Hagmann, W. K.; Evans, D. C.; Kumar, S. Addressing the metabolic activation potential of new leads in drug discovery: a case study using ion trap mass spectrometry and tritium labeling techniques. J. Mass Spectrom. 2003, 38, 211–221. (133) Chien, R. J.; Corey, E. J. Strong conformational preferences of heteroaromatic ethers and electron pair repulsion. Org. Lett. 2010, 12, 132–135. (134) Phillips, G. B.; Buckman, B. O.; Davey, D. D.; Eagen, K. A.; Guilford, W. J.; Hinchman, J.; Ho, E.; Koovakkat, S.; Liang, A.; Light, D. R.; Mohan, R.; Ng, H. P.; Post, J. M.; Shaw, K. J.; Smith, D.; Subramanyam, B.; Sullivan, M. E.; Trinh, L.; Vergona, R.; Walters, J.; White, K.; Whitlow, M.; Wu, S.; Xu, W.; Morrissey, M. M. Discovery of N-[2-[5-[amino(imino)methyl]-2-hydroxyphenoxy]-3, 5-difluoro6-[3-(4,5-dihydro-1-methyl-1H-imidazol-2-yl)phenoxy]pyridin-4-yl]N-methylglycine (ZK-807834): a potent, selective, and orally active inhibitor of the blood coagulation enzyme factor Xa. J. Med. Chem. 1998, 41, 3557–3562. (135) Phillips, G.; Davey, D. D.; Eagen, K. A.; Koovakkat, S. K.; Liang, A.; Ng, H. P.; Pinkerton, M.; Trinh, L.; Whitlow, M.; Beatty, A. M.; Morrissey, M. M. Design, synthesis, and activity of 2,6-diphenoxypyridinederived factor Xa inhibitors. J. Med. Chem. 1999, 42, 1749–1756. (136) Adler, M.; Davey, D. D.; Phillips, G. B.; Kim, S.-H.; Jancarik, J.; Rumennik, G.; Light, D. R.; Whitlow, M. Preparation, characterization, and the crystal structure of the inhibitor ZK-807834 (CI-1031) complexed with factor Xa. Biochemistry 2000, 39, 12534–12542. (137) Atwal, K. S.; Rovnyak, G. C.; Schwartz, J.; Moreland, S.; Hedberg, A.; Gougoutas, J. Z.; Malley, M. M.; Floyd, D. M. Dihydropyrimidine calcium channel blockers: 2-heterosubstituted 4-aryl-1,4dihydro-6-methyl-5-pyrimidinecarboxylic acid esters as potent mimics of dihydropyridines. J. Med. Chem. 1990, 33, 1510–1515. (138) Atwal, K. S.; Rovnyak, G. C.; Kimball, S. D.; Floyd, D. M.; Moreland, S.; Swanson, B. N.; Gougoutas, J. Z.; Schwartz, J.; Smillie, K. M.; Malley, M. F. Dihydropyrimidine calcium channel blockers. 2. 2583 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry 3-Substituted-4-aryl-1,4-dihydro-6-methyl-5-pyrimidinecarboxylc acid esters as potent mimics of dihydropyridines. J. Med. Chem. 1990, 33, 2629–2635. (139) Atwal, K. S.; Swanson, B. N.; Unger, S. E.; Floyd, D. M.; Moreland, S.; Hedberg, A.; O’Reilly, B. C. Dihydropyrimidine calcium channel blockers. 3. 3-Carbamoyl-4-aryl-1,2,3,4-tetrahydro-6-methyl-5pyrimidinecarboxylic acid esters as orally effective antihypertensive agents. J. Med. Chem. 1991, 34, 806–811. (140) Rovnyak, G. C.; Atwal, K. S.; Hedberg, A.; Kimball, S. D.; Moreland, S.; Gougoutas, J. Z.; O’Reilly, B. C.; Schwartz, J.; Malley, M. F. Dihydropyrimidine calcium channel blockers. 4. Basic 3-substituted-4aryl-1,4-dihydropyrimidine-5-carboxylic acid esters. Potent antihypertensive agents. J. Med. Chem. 1992, 35, 3254–3263. (141) Nagarathnam, D.; Miao, S. W.; Lagu, B.; Chiu, G.; Fang, J.; Dhar, T. G. M.; Zhang, J.; Tyagarajan, S.; Marzabadi, M. R.; Zhang, F.; Wong, W. C.; Sun, W.; Tian, D.; Wetzel, J. M.; Forray, C.; Chang, R. S. L.; Broten, T. P.; Ransom, R. W.; Schorn, T. W.; Chen, T. B.; O’Malley, S.; Kling, P.; Schneck, K.; Bendesky, R.; Harrell, C. M.; Vyas, K. P.; Gluchowski, C. Design and synthesis of novel R1a adrenoceptorselective antagonists. 1. Structure-activity relationship in dihydropyrimidinones. J. Med. Chem. 1999, 42, 4764–4777. (142) Wong, W. C.; Sun, W.; Lagu, B.; Tian, D.; Marzabadi, M. R.; Zhang, F.; Nagarathnam, D.; Miao, S. W.; Wetzel, J. M.; Peng, J.; Forray, C.; Chang, R. S. L.; Chen, T. B.; Ransom, R.; O’Malley, S.; Broten, T. P.; Kling, P.; Vyas, K. P.; Zhang, K.; Gluchowski, C. Design and synthesis of novel R1a adrenoceptor-selective antagonists. 4. Structure-activity relationship in the dihydropyrimidine series. J. Med. Chem. 1999, 42, 4804–4813. (143) Qiao, J. X.; Cheney, D. L.; Alexander, R. S.; Smallwood, A. M.; King, S. R.; He, K.; Rendina, A. R.; Luettgen, J. M.; Knabb, R. M.; Wexler, R. R.; Lam, P. Y. S. Achieving structural diversity using the perpendicular conformation of alpha-substituted phenylcyclopropanes to mimic the bioactive conformation of ortho-substituted biphenyl P4 moieties: discovery of novel, highly potent inhibitors of factor Xa. Bioorg. Med. Chem. Lett. 2008, 18, 4118–4123. (144) Pellicciari, R.; Raimondo, M.; Marinozzi, M.; Natalini, B.; Costantino, G; Thomsen, C. (S)-(þ)-2-(30 -Carboxybicyclo[1.1.1]pentyl)glycine, a structurally new group 1 metabotropic glutamate receptor antagonist. J. Med. Chem. 1996, 39, 2874–2876. (145) Pellicciari, R.; Costantino, G.; Giovagnoni, E.; Mattoli, L.; Brabet, I.; Pin, J.-P. Synthesis and preliminary evaluation of (S)-2-(40 carboxycubyl)glycine, a new selective mGluR1 antagonist. Bioorg. Med. Chem. Lett. 1998, 8, 1569–1574. (146) Costantino, G.; Maltoni, K.; Marinozzi, M.; Camaioni, E.; Prezeau, L.; Pin, J.-P.; Pellicciari, R. Synthesis and biological evaluation of 2-(30 -(1H-tetrazol-5-yl)bicyclo[1.1.1]pent-1-yl)glycine (S-TBPG), a novel mGlu1 receptor antagonist. Bioorg. Med. Chem. 2001, 9, 221–227. (147) Brown, A.; Brown, T. B.; Calabrese, A.; Ellis, D.; Puhalo, N.; Ralph, M.; Watson, L. Triazole oxytocin antagonists: identification of an aryloxyazetidine replacement for a biaryl substituent. Bioorg. Med. Chem. Lett. 2010, 20, 516–520. (148) Lovering, F.; Bikker, J.; Humblet, C. Escape from flatland: increasing saturation as an approach to improving clinical success. J. Med. Chem. 2009, 52, 6752–6756. (149) Wu, W.-L.; Burnett, D. A.; Spring, R.; Greenlee, W. J.; Smith, M.; Favreau, L.; Fawzi, A.; Zhang, H.; Lachowicz, J. E. Dopamine D1/D5 receptor antagonists with improved pharmacokinetics: design, synthesis, and biological evaluation of phenol bioisosteric analogues of benzazepine D1/D5 antagonists. J. Med. Chem. 2005, 48, 680–693. (150) Reggelin, M.; Zur, C. Sulfoximines. Structures, properties, and synthetic applications. Synthesis 2000, 1–64. (151) Bentley, H. R.; McDermott, E. E.; Whitehead, J. K. Action of nitrogen trichloride on proteins: synthesis of the toxic factor from methionine. Nature 1950, 165, 735. (152) Satzinger, G. Drug discovery and commercial exploitation. Drug News Perspect. 2001, 14, 197–207. (153) Lua, D.; Vince, R. Discovery of potent HIV-1 protease inhibitors incorporating sulfoximine functionality. Bioorg. Med. Chem. Lett. 2007, 17, 5614–5619. PERSPECTIVE (154) Lu, D.; Sham, Y. Y.; Vince, R. Design, asymmetric synthesis, and evaluation of pseudosymmetric sulfoximine inhibitors against HIV-1 protease. Bioorg. Med. Chem. 2010, 18, 2037–2048. (155) Raza, A.; Sham, Y. Y.; Vince, R. Design and synthesis of sulfoximine-based inhibitors for HIV-1 protease. Bioorg. Med. Chem. Lett. 2008, 18, 5406–5410. (156) Erickson, J. A.; McLoughlin, J. I. Hydrogen bond donor properties of the difluoromethyl group. J. Org. Chem. 1995, 60, 1626–1631. (157) For example, cLogP values calculated using the chemical properties function of ChemDraw Ultra, version 9, are as follows: PhOH, 1.48; PhNH2, 0.92; PhCHF2, 2.34; PhCH2OH, 1.10; PhCH2NH2, 1.09; PhCH2CHF2, 2.32. (158) Narjes, F.; Koehler, K. F.; Koch, U.; Gerlach, B.; Colarusso, S.; Steink€uhler, C.; Brunetti, M.; Altamura, S.; De Francesco, R.; Matassa, V. G. A designed P1 cysteine mimetic for covalent and non-covalent inhibitors of HCV NS3 protease. Bioorg. Med. Chem. Lett. 2002, 12, 701– 704. (159) Xu, Y.; Qian, L.; Pontsler, A. V.; McIntyre, T. M.; Prestwich, G. D. Synthesis of difluoromethyl substituted lysophosphatidic acid analogues. Tetrahedron 2004, 60, 43–49. (160) Xu, Y.; Prestwich, G. D. Concise synthesis of acyl migrationblocked 1,1-difluorinated analogues of lysophosphatidic acid. J. Org. Chem. 2002, 67, 7158–7161. (161) Sheppeck, J. E., II; Gilmore, J. L.; Yang, A.; Chen, X.-T.; Xue, C.-B.; Roderick, J.; Liu, R.-Q.; Covington, M. B.; Decicco, C. P.; Duan, J.J.-W. Discovery of novel hydantoins as selective non-hydroxamate inhibitors of tumor necrosis factor-R converting enzyme (TACE). Bioorg. Med. Chem. Lett. 2007, 17, 1413–1417. (162) Flipo, M.; Charton, J.; Hocine, A.; Dassonneville, S.; Deprez, B.; Deprez-Poulain, R. Hydroxamates: relationships between structure and plasma stability. J. Med. Chem. 2009, 52, 6790–6802. (163) Watanabe, T. Investigational histone deacetylase inhibitors for non-Hodgkin lymphomas. Expert Opin. Invest. Drugs 2010, 19, 1113– 1127. (164) Chowdhury, M. A.; Abdellatif, K. R. A.; Dong, Y.; Das, D.; Suresh, M. R.; Knaus, E. E. Synthesis of celecoxib analogues possessing a N-difluoromethyl-1,2-dihydropyrid-2-one 5-lipoxygenase pharmacophore: biological evaluation as dual inhibitors of cyclooxygenases and 5-lipoxygenase with anti-inflammatory activity. J. Med. Chem. 2009, 52, 1525–1529. (165) Chowdhury, M. A.; Chen, H.; Abdellatif, K. R. A.; Dong, Y.; Petruk, K. C.; Knaus, E. E. Synthesis and biological evaluation of 1-(benzenesulfonamido)-2-[5-(N-hydroxypyridin-2(1H)one)]acetylene regioisomers: a novel class of 5-lipoxygenase inhibitors. Bioorg. Med. Chem. Lett. 2008, 18, 4195–4198. (166) Chowdhury, M. A.; Abdellatif, K. R. A.; Dong, Y.; Rahman, M.; Das, D.; Suresh, M. R.; Knaus, E. E. Synthesis of 1-(methanesulfonyland aminosulfonylphenyl)acetylenes that possess a 2-(N-difluoromethyl-1,2-dihydropyridin-2-one) pharmacophore: evaluation as dual inhibitors of cyclooxygenases and 5-lipoxygenase with anti-inflammatory activity. Bioorg. Med. Chem. Lett. 2009, 19, 584–588. (167) Chowdhury, M. A.; Abdellatif, K. R. A.; Dong, Y.; Das, D.; Yu, G.; Velazquez, C. A.; Suresh, M. R.; Knaus, E. E. Synthesis and biological evaluation of salicylic acid and N-acetyl-2-carboxybenzenesulfonamide regioisomers possessing a N-difluoromethyl-1,2-dihydropyrid-2-one pharmacophore: dual inhibitors of cyclooxygenases and 5-lipoxygenase with anti-inflammatory activity. Bioorg. Med. Chem. Lett. 2009, 19, 6855–6861. (168) Yu, G.; Praveen Rao, P. N.; Chowdhury, M. A.; Abdellatif, K. R. A.; Dong, Y.; Das, D.; Velazquez, C. A.; Suresh, M. R.; Knaus, E. E. Synthesis and biological evaluation of N-difluoromethyl-1,2-dihydropyrid-2-one acetic acid regioisomers: dual inhibitors of cyclooxygenases and 5-lipoxygenase. Bioorg. Med. Chem. Lett. 2010, 20, 2168–2173. (169) Yu, G.; Chowdhury, M. A.; Abdellatif, K. R. A.; Dong, Y.; Praveen Rao, P. N.; Das, D.; Velazquez, C. A.; Suresh, M. R.; Knaus, E. E. Phenylacetic acid regioisomers possessing a N-difluoromethyl-1,2-dihydropyrid-2-one pharmacophore: evaluation as dual inhibitors of cyclooxygenases and 5-lipoxygenase with anti-inflammatory activity. Bioorg. Med. Chem. Lett. 2010, 20, 896–902. 2584 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry (170) Chowdhury, M. A.; Huang, Z.; Abdellatif, K. R. A.; Dong, Y.; Yu, G.; Velazquez, C. A.; Knaus, E. E. Synthesis and biological evaluation of indomethacin analogs possessing a N-difluoromethyl-1,2-dihydropyrid-2-one ring system: a search for novel cyclooxygenase and lipoxygenase inhibitors. Bioorg. Med. Chem. Lett. 2010, 20, 5776–5780. (171) Scolnick, L. R.; Clements, A. M.; Liao, J.; Crenshaw, L.; Hellberg, M.; May, J.; Dean, T. R.; Christianson, D. W. Novel binding mode of hydroxamate inhibitors to human carbonic anhydrase II. J. Am. Chem. Soc. 1997, 119, 850–851. (172) Sheppeck, J. E., II; Tebben, A.; Gilmore, J. L.; Yang, A.; Wasserman, Z. R.; Decicco, C. P.; Duan, J.J.-W. A molecular modeling analysis of novel non-hydroxamate inhibitors of TACE. Bioorg. Med. Chem. Lett. 2007, 17, 1408–1412. (173) Yu, W.; Guo, Z.; Orth, P.; Madison, V.; Chen, L.; Dai, C.; Feltz, R. J.; Girijavallabhan, V. M.; Kim, S. H.; Kozlowski, J. A.; Lavey, B. J.; Li, D.; Lundell, D.; Niu, X.; Piwinski, J. J.; Popovici-Muller, J.; Rizvi, R.; Rosner, K. E.; Shankar, B. B.; Shih, N.-Y.; Siddiqui, M. A.; Sun, J.; Tong, L.; Umland, S.; Wong, M. K. C.; Yang, D.-y.; Zhou, G. Discovery and SAR of hydantoin TACE inhibitors. Bioorg. Med. Chem. Lett. 2010, 20, 1877–1880. (174) Li, C.; Benet, L. Z.; Grillo, M. P. Studies on the chemical reactivity of 2-phenylpropionic acid 1-O-acyl glucuronide and S-acylCoA thioester metabolites. Chem. Res. Toxicol. 2002, 5, 1309–1317. (175) Carini, D. J.; Christ, D. D.; Duncia, J. V.; Pierce, M. E. The discovery and development of angiotensin II antagonists. Pharm. Biotechnol. 1998, 11, 29–56. (176) Naylor, E. M.; Chakravarty, P. K.; Costello, C. A.; Chang, R. S.; Chen, T.-B.; Faust, K. A.; Lotti, V. J.; Kivlighn, S. D.; Zingaro, G. J.; Siegl, P. K. S.; Wong, P. C.; Carini, D. J.; Wexler, R. R.; Patchett, A. A.; Greenlee, W. J. Potent imidazole angiotensin II antagonists: acyl sulfonamides and acyl sulfamides as tetrazole replacements. Bioorg. Med. Chem. Lett. 1993, 3, 69–74. (177) Chakravarty, P. K.; Naylor, E. M.; Chen, A.; Chang, R. S. L.; Chen, T.-B.; Faust, K. A.; Lotti, V. J.; Kivlighn, S. D.; Gable, R. A.; Zingaro, G. J.; Schorn, T. W.; Schaffer, L. W.; Broten, T. P.; Siegl, P. K. S.; Patchett, A. A.; Greenlee, W. J. A highly potent, orally active imidazo[4,5-b] pyridine biphenylacylsulfonamide (MK-996; L-159,282): a new AT1selective angiotensin II receptor antagonist. J. Med. Chem. 1994, 37, 4068–4072. (178) Scola, P. M.; Sun, L.-Q.; Chen, J.; Wang, A. X.; Sit, S.-Y.; Chen, Y.; D’Andrea, S. V.; Zheng, Z.; Sin, N.; Venables, B. L.; Cocuzza, A.; Bilder, D.; Carini, D.; Johnson, B.; Good, A. C.; Rajamani, R.; Klei, H. E.; Friborg, J.; Barry, D.; Levine, S.; Chen, C.; Sheaffer, A.; Hernandez, D.; Falk, P.; Yu, F.; Zhai, G.; Knipe, J. O.; Mosure, K.; Shu, Y.-Z.; Phillip, T.; Arora, V. K.; Loy, J.; Adams, S.; Schartman, R.; Browning, M.; Levesque, P. C.; Li, D.; Zhu, J. L.; Sun, H.; Pilcher, G.; Bounous, D.; Lange, R. W.; Pasquinelli, C.; Eley, T.; Colonno, R.; Meanwell, N. A.; McPhee. F. Discovery of BMS-650032, an NS3 Protease Inhibitor for the Treatment of Hepatitis C. Presented at the 239th National Meeting and Exposition of the American Chemical Society, San Francisco, CA, March 21-25, 2010; MEDI-38. (179) Chen, K. X.; Njoroge, F. G. A review of HCV protease inhibitors. Curr. Opin. Invest. Drugs 2009, 10, 821–837. (180) Asada, M.; Obitsu, T.; Kinoshita, A.; Nakai, Y.; Nagase, T.; Sugimoto, I.; Tanaka, M.; Takizawa, H.; Yoshikawa, K.; Sato, K.; Narita, M.; Ohuchida, S.; Nakai, H.; Toda, M. Discovery of novel N-acylsulfonamide analogs as potent and selective EP3 receptor antagonists. Bioorg. Med. Chem. Lett. 2010, 20, 2639–2643. (181) Wendt, M. D. Discovery of ABT-263, a Bcl-family protein inhibitor: observations on targeting a large protein-protein interaction. Expert Opin. Drug Discovery 2008, 3, 1123–1143. (182) Park, C.-M.; Bruncko, M.; Adickes, J.; Bauch, J.; Ding, H.; Kunzer, A.; Marsh, K. C.; Nimmer, P.; Shoemaker, A. R.; Song, X.; Tahir, S. K.; Tse, C.; Wang, X.; Wendt, M. D.; Yang, X.; Zhang, H.; Fesik, S. W.; Rosenberg, S. H.; Elmore, S. W. Discovery of an orally bioavailable small molecule inhibitor of prosurvival B-cell lymphoma 2 proteins. J. Med. Chem. 2008, 51, 6902–6915. PERSPECTIVE (183) Gruttadauria, M.; Giacalone, F.; Noto, R. Supported proline and proline-derivatives as recyclable organocatalysts. Chem. Soc. Rev. 2008, 37, 1666–1688. (184) Berkessel, A.; Koch, B.; Lex, J. Proline-derived N-sulfonylcarboxamides: readily available, highly enantioselective and versatile catalysts for direct aldol reactions. Adv. Synth. Catal. 2004, 346, 1141– 1146. (185) Qiu, J.; Stevenson, S. H.; O’Beirne, M. J.; Silverman, R. B. 2,6Difluorophenol as a bioisostere of a carboxylic acid: bioisosteric analogues of γ-aminobutyric acid. J. Med. Chem. 1999, 42, 329–332. (186) The log P, cLogP, and tPSA data for 25 and 208-211 were derived using the chemical properties function of ChemDraw Ultra, version 9. (187) Nicolaou, I.; Zika, C.; Demopoulos, V. J. [1-(3,5-Difluoro-4hydroxyphenyl)-1H-pyrrol-3-yl]phenylmethanone as a bioisostere of a carboxylic acid aldose reductase inhibitor. J. Med. Chem. 2004, 47, 2706–2709. (188) Soll, R. M.; Kinney, W. A.; Primeau, J.; Ganick, L.; McCaully, R. J.; Colatsky, T.; Oshii, G.; Park, C. H.; Harmpee, D.; White, V.; McCallum, J.; Russo, A.; Dinish, J.; Wojdan, A. 3-Hydroxy-3-cyclobutene-1,2-dione: application of a novel carboxylic acid bioisostere to an in vivo active non-tetrazole angiotensin II antagonist. Bioorg. Med. Chem. Lett. 1993, 3, 757–760. (189) Kinney, W. A.; Lee, N. E.; Garrison, D. T.; Podlesny, E. J., Jr.; Simmonds, J. T.; Bramlett, D.; Notvest, R. R.; Kowal, D. M.; Tasse, R. P. Bioisosteric replacement of the R-amino carboxylic acid functionality in 2-amino-5-phosphonopentanoic acid yields unique 3,4-diamino-3cyclobutene-1,2-dione-containing NMDA antagonists. J. Med. Chem. 1992, 35, 4720–4726. (190) Catarzi, D.; Colotta, V.; Varano, F. Competitive AMPA receptor antagonists. Med. Res. Rev. 2007, 27, 239–278. (191) Kuduk, S. D.; Ng, C.; Feng, D.-M.; Wai, J. M.-C.; Chang, R. S. L.; Harrell, C. M.; Murphy, K. L.; Ransom, R. W.; Reiss, D.; Ivarsson, M.; Mason, G.; Boyce, S.; Tang, C.; Prueksaritanont, T.; Freidinger, R. M.; Pettibone, D. J.; Bock, M. G. 2,3-Diaminopyridine bradykinin B1 receptor antagonists. J. Med. Chem. 2004, 47, 6439–6442. (192) Tang, C.; Subramanian, R.; Kuo, Y.; Krymgold, S.; Lu, P.; Kuduk, S. D.; Ng, C.; Feng, D.-M.; Elmore, C.; Soli, E.; Ho, J.; Bock, M. G.; Baillie, T. A.; Prueksaritanont, T. Bioactivation of 2,3-diaminopyridine-containing bradykinin B1 receptor antagonists: irreversible binding to liver microsomal proteins and formation of glutathione conjugates. Chem. Res. Toxicol. 2005, 18, 934–945. (193) Wood, M. R.; Schirripa, K. M.; Kim, J. J.; Wan, B.-L.; Murphy, K. L.; Ransom, R. W.; Chang, R. S. L.; Tang, C.; Prueksaritanont, T.; Detwiler, T. J.; Hettrick, L. A.; Landis, E. R.; Leonard, Y. M.; Krueger, J. A.; Lewis, S. D.; Pettibone, D. J.; Freidinger, R. M.; Bock, M. G. Cyclopropylamino acid amide as a pharmacophoric replacement for 2,3-diaminopyridine. Application to the design of novel bradykinin B1 receptor antagonists. J. Med. Chem. 2006, 49, 1231–1234. (194) Jung, M. E.; Piizzi, G. gem-Disubstituent effect: theoretical basis and synthetic applications. Chem. Rev. 2005, 105, 1735–1766. (195) Laurence., C.; Berthelot, M. Observations on the strength of hydrogen bonding. Perspect. Drug Discovery Des. 2000, 18, 39–60. (196) Laurence, C.; Brameld, K. A.; Graton, J.; Le Questel, J.-Y.; Renault, E. The pKBHX database: toward a better understanding of hydrogen-bond basicity for medicinal chemists. J. Med. Chem. 2009, 52, 4073–4086. (197) Abraham, M. H.; Duce, P. P.; Prior, D,V. Hydrogen bonding. Part 9. Solute proton donor and proton acceptor scales for use in drug design. J. Chem. Soc., Perkin Trans. 2 1989, 1355–1375. (198) Nobeli, I.; Price, S. L.; Lommerse, J. P. M.; Taylor, R. Hydrogen bonding properties of oxygen and nitrogen acceptors in aromatic heterocycles. J. Comput. Chem. 1997, 18, 2060–2074. (199) Graton, J.; Berthelot, M.; Gal, J.-F.; Laurence, C.; Lebreton, J.; Le Questel, J.-Y.; Maria, P.-C.; Robins, R. The nicotinic pharmacophore: thermodynamics of the hydrogen-bonding complexation of nicotine, nornicotine, and models. J. Org. Chem. 2003, 68, 8208– 8221. 2585 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry (200) Arnaud, V.; Le Questel, J.-Y.; Mathe-Allainmat, M.; Lebreton, J.; Berthelot, M. Multiple hydrogen-bond accepting capacities of polybasic molecules: the case of cotinine. J. Phys. Chem. A 2004, 108, 10740–10748. (201) Locati, A.; Berthelot, M.; Evain, M.; Lebreton, J.; Le Questel, J.-Y.; Mathe-Allainmat, M.; Planchat, A.; Renault, E.; Graton, J. The exceptional hydrogen-bond properties of neutral and protonated lobeline. J. Phys. Chem. A 2007, 111, 6397–6405. (202) Arnaud, V.; Berthelot, M.; Evain, M.; Graton, J.; Le Questel, J.-Y. Hydrogen-bond interactions of nicotine and acetylcholine salts: a combined crystallographic, spectroscopic, thermodynamic and theoretical study. Chem.-Eur. J. 2007, 13, 1499–1510. (203) Arnaud, V.; Berthelot, M.; Le Questel, J.-Y. Hydrogen-bond accepting strength of protonated nicotine. J. Phys. Chem. A 2005, 109, 3767–3770. (204) Arnaud, V.; Berthelot, M.; Felpin, F.-X.; Lebreton, J.; Le Questel, J.-Y.; Graton, J. Hydrogen-bond accepting strength of five-membered N-heterocycles: the case of substituted phenylpyrrolines and myosmines. Eur. J. Org. Chem. 2009, 4939–4948. (205) Graton, J.; Berthelot, M.; Gal, J.-F.; Girard, S.; Laurence, C.; Lebreton, J.; Le Questel, J.-Y.; Maria, P.-C.; Naus, P. Site of protonation of nicotine and nornicotine in the gas phase: pyridine or pyrrolidine nitrogen? J. Am. Chem. Soc. 2002, 124, 10552–10562. (206) Taft, R. W.; Anvia, F.; Taagpera, M.; Catalan, J.; Elguero, J. Electrostatic proximity effects in the relative basicities and acidities of pyrazole, imidazole, pyridazine, and pyrimidine. J. Am. Chem. Soc. 1986, 108, 3237–3239. (207) Johnson, D. S.; Stiff, C.; Lazerwith, S. E.; Kesten, S. R.; Fay, L. K.; Morris, M.; Beidler, D.; Liimatta, M. B.; Smith, S. E.; Dudley, D. T.; Sadagopan, N.; Bhattachar, S. N.; Kesten, S. J.; Nomanbhoy, T. K.; Cravatt, B. F.; Ahn, K. Discovery of PF-04457845: a highly potent, orally bioavailable, and selective urea FAAH inhibitor. ACS Med. Chem. Lett. 2011, 2, 91-96. (208) Herberich, B.; Cao, G.-Q.; Chakrabarti, P. P.; Falsey, J. R.; Pettus, L.; Rzasa, R. M.; Reed, A. B.; Reichelt, A.; Sham, K.; Thaman, M.; Wurz, R. P.; Xu, S.; Zhang, D.; Hsieh, F.; Lee, M. R.; Syed, R.; Li, V.; Grosfeld, D.; Plant, M. H.; Henkle, B.; Sherman, L.; Middleton, S.; Wong, L. M.; Tasker, A. S. Discovery of highly selective and potent p38 inhibitors based on a phthalazine scaffold. J. Med. Chem. 2008, 51, 6271–6279. (209) Pettus, L. H.; Xu, S.; Cao, G.-Q.; Chakrabarti, P. P.; Rzasa, R. M.; Sham, K.; Wurz, R. P.; Zhang, D.; Middleton, S.; Henkle, B.; Plant, M. H.; Saris, C. J. M.; Sherman, L.; Wong, L. M.; Powers, D. A.; Tudor, Y.; Yu, V.; Lee, M. R.; Syed, R.; Hsieh, F.; Tasker, A. S. 3-Amino7-phthalazinylbenzoisoxazoles as a novel class of potent, selective, and orally available inhibitors of p38R mitogen-activated protein kinase. J. Med. Chem. 2008, 51, 6280–6292. (210) Wu, B.; Wang, H.-L.; Pettus, L.; Wurz, R. P.; Doherty, E. M.; Henkle, B.; McBride, H. J.; Saris, C. J. M.; Wong, L. M.; Plant, M. H.; Sherman, L.; Lee, M. R.; Hsieh, F.; Tasker, A. S. Discovery of pyridazinopyridinones as potent and selective p38 mitogen-activated protein kinase inhibitors. J. Med. Chem. 2010, 53, 6398–6411. (211) Berthelot, M.; Laurence, C.; Safar, M.; Besseau, F. Hydrogenbond basicity pKHB scale of six-membered aromatic N-heterocycles. J. Chem. Soc., Perkin Trans. 2 1998, 283–290. (212) Dombroski, M. A.; Letavic, M. A.; McClure, K. F.; Barberia, J. T.; Carty, T. J.; Cortina, S. R.; Csiki, C.; Dipesa, A. J.; Elliott, N. C.; Gabel, C. A.; Jordan, C. K.; Labasi, J. M.; Martin, W. H.; Peese, K. M.; Stock, I. A.; Svensson, L.; Sweeney, F. J.; Yu, C. H. Benzimidazolone p38 inhibitors. Bioorg. Med. Chem. Lett. 2004, 14, 919–923. (213) McClure, K. F.; Abramov, Y. A.; Laird, E. R.; Barberia, J. T.; Cai, W.; Carty, T. J.; Cortina, S. R.; Danley, D. E.; Dipesa, A. J.; Donahue, K. M.; Dombroski, M. A.; Elliott, N. C.; Gabel, C. A.; Han, S.; Hynes, T. R.; LeMotte, P. K.; Mansour, M. N.; Marr, E. S.; Letavic, M. A.; Pandit, J.; Ripin, D. B.; Sweeney, F. J.; Tan, D.; Tao, Y. Theoretical and experimental design of atypical kinase inhibitors: application to p38 MAP kinase. J. Med. Chem. 2005, 48, 5728–5737. (214) B€ohm, H.-J.; Klebe, G.; Brode, S.; Hesse, U. Oxygen and nitrogen in competitive situations: which is the hydrogen-bond acceptor? Chem.-Eur. J. 1996, 2, 1509–1513. PERSPECTIVE (215) Meanwell, N. A.; Rosenfeld, M. J.; Wright, J. J. K.; Brassard, C. L.; Buchanan, J. O.; Federici, M. E.; Fleming, J. S.; Gamberdella, M.; Hartl, K. S.; Zavoico, G. B.; Seiler, S. M. Nonprostanoid prostacyclin mimetics. 4. Derivatives of 2-[3-[2-(4,5-diphenyl-2-oxazolyl)ethyl]phenoxy]acetic acid substituted R to the oxazole ring. J. Med. Chem. 1993, 36, 3871–3883. (216) Meanwell, N. A.; Romine, J. L.; Rosenfeld, M. J.; Martin, S. W.; Trehan, A. K.; Wright, J. J. K.; Malley, M. F.; Gougoutas, J. Z.; Brassard, C. L.; Buchanan, J. O.; Federici, M. E.; Fleming, J. S.; Gamberdella, M.; Hartl, K. S.; Zavoico, G. B.; Seiler, S. M. Nonprostanoid prostacyclin mimetics. 5. Structure-activity relationships associated with [3-[4-(4,5diphenyl-2-oxazolyl)-5-oxazolyl]phenoxy]acetic acid. J. Med. Chem. 1992, 36, 3884–3903. (217) Gougoutas, J. Z.; Ojala, W. H.; Malley, M. F. 3,4-Bis(4-chloropheny1)sydnone. Cryst. Struct. Commun. 1982, 11, 1731– 1736. (218) Sweet, F.; Boyd, J.; Medina, O.; Konderski, L.; Murdock, G. L. Hydrogen bonding in steroidogenesis: studies in new heterocyclic analogues of estrone that inhibit human estradiol 17β-dehydrogenase. Biochem. Biophys. Res. Commun. 1991, 180, 1057–1063. (219) Cai, J.; Fradera, X.; van Zeeland, M.; Dempster, M.; Cameron, K. S.; D. Bennett, J.; Robinson, J.; Popplestone, L.; Baugh, M.; Westwood, P.; Bruin, J.; Hamilton, W.; Kinghorn, E.; Long, C.; Uitdehaag, J. C. M. 4-(3-Trifluoromethylphenyl)-pyrimidine-2-carbonitrile as cathepsin S inhibitors: N3, not N1 is critically important. Bioorg. Med. Chem. Lett. 2010, 20, 4507–4510. (220) Jones, E. D.; Vandegraaff, N.; Le, G.; Choi, N.; Issa, W.; MacFarlane, K.; Thienthong, N.; Winfield, L. J.; Coates, J. A. V.; Lu, L.; Li, X.; Feng, X.; Yu, C.; Rhodes, D. I.; Deadman, J. J. Design of a series of bicyclic HIV-1 integrase inhibitors. Part 1: selection of the scaffold. Bioorg. Med. Chem. Lett. 2010, 20, 5913–5917. (221) Le, G.; Vandegraaff, N.; Rhodes, D. I.; Jones, E. D.; Coates, J. A. V.; Thienthong, N.; Winfield, L. J.; Lu, L.; Li, X.; Yu, C.; Feng, X.; Deadman, J. J. Design of a series of bicyclic HIV-1 integrase inhibitors. Part 2: Azoles: effective metal chelators. Bioorg. Med. Chem. Lett. 2010, 20, 5909–5912. (222) Le, G.; Vandegraaff, N.; Rhodes, D. I.; Jones, E. D.; Coates, J. A. V.; Lu, L.; Li, X.; Yu, C.; Feng, X.; Deadman, J. J. Discovery of potent HIV integrase inhibitors active against raltegravir resistant viruses. Bioorg. Med. Chem. Lett. 2010, 20, 5013–5018. (223) Johns, B. A.; Weatherhead, J. G.; Allen, S. H.; Thompson, J. B.; Garvey, E. P.; Foster, S. A.; Jeffrey, J. L.; Miller, W. H. The use of oxadiazole and triazole substituted naphthyridines as HIV-1 integrase inhibitors. Part 1: Establishing the pharmacophore. Bioorg. Med. Chem. Lett. 2009, 19, 1802–1806. (224) Johns, B. A.; Weatherhead, J. G.; Allen, S. H.; Thompson, J. B.; Garvey, E. P.; Foster, S. A.; Jeffrey, J. L.; Miller, W. H. 1,3,4-Oxadiazole substituted naphthyridines as HIV-1 integrase inhibitors. Part 2: SAR of the C5 position. Bioorg. Med. Chem. Lett. 2009, 19, 1807–1810. (225) Desiraju, G. R.; Steinter, T. The Weak Hydrogen Bond in Structural Chemistry and Biology; Oxford University Press: Oxford, U. K., 1999. (226) Pierce, A. C.; Sandretto, K. L.; Bemis, G. W. Kinase inhibitors and the case for CH 3 3 3 O hydrogen bonds in protein-ligand binding. Proteins 2002, 49, 567–576. (227) Pierce, A. C.; ter Haar, E.; Binch, H. M.; Kay, D. P.; Patel, S. R.; Li, P. CH 3 3 3 O and CH 3 3 3 N hydrogen bonds in ligand design: a novel quinazolin-4-ylthiazol-2-ylamine protein kinase inhibitor. J. Med. Chem. 2005, 48, 1278–1281. (228) Ioannidis, S.; Lamb, M. L.; Davies, A. M.; Almeida, L.; Su, M.; Bebernitz, G.; Ye, M.; Bell, K.; Alimzhanov, M.; Zinda, M. Discovery of pyrazol-3-ylamino pyrazines as novel JAK2 inhibitors. Bioorg. Med. Chem. Lett. 2009, 19, 6524–6528. (229) Ioannidis, S.; Lamb, M. L.; Almeida, L.; Guan, H.; Peng, B.; Bebernitz, G.; Bell, K.; Alimzhanov, M.; Zinda, M. Replacement of pyrazol-3-yl amine hinge binder with thiazol-2-yl amine: discovery of potent and selective JAK2 inhibitors. Bioorg. Med. Chem. Lett. 2010, 20, 1669–1673. 2586 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry (230) Lin, S.; Wrobleski, S. T.; Hynes, J., Jr.; Pitt, S.; Zhang, R.; Fan, Y.; Doweyko, A. M.; Kish, K. F.; Sack, J. S.; Malley, M. F.; Kiefer, S. E.; Newitt, J. A.; McKinnon, M.; Trzaskos, J.; Barrish, J. C.; Dodd, J. H.; Schieven, G. L.; Leftheris, K. Utilization of a heteroatom-sulfur nonbonding interaction in the design of new 2-aminothiazol-5-yl-pyrimidines as p38R MAP kinase inhibitors. Bioorg. Med. Chem. Lett. 2010, 20, 5864–5868. (231) Hynes, J., Jr.; Wu, H.; Pitt, S.; Shen, D.-R.; Zhang, R.; Schieven, G. L.; Gillooly, K. M.; Shuster, D. J.; Taylor, T. L.; Yang, X.; McIntyre, K. W.; McKinnon, M.; Zhang, H.; Marathe, P. H.; Doweyko, A. M.; Kish, K.; Kiefer, S. E.; Sack, J. S.; Newitt, J. A.; Barrish, J. C.; Dodd, J.; Leftheris, K. The discovery of (R)-2-(sec-butylamino)-N-(2-methyl5-(methylcarbamoyl)phenyl)thiazole-5-carboxamide (BMS-640994), a potent and efficacious p38R MAP kinase inhibitor. Bioorg. Med. Chem. Lett. 2008, 18, 1762–1767. (232) Iwaoka, M.; Takemoto, S.; Tomoda, S. Statistical and theoretical investigations on the directionality of nonbonded S 3 3 3 O interactions. Implications for molecular design and protein engineering. J. Am. Chem. Soc. 2002, 124, 10613–10620. (233) Haginoya, N.; Kobayashi, S.; Komoriya, S.; Yoshino, T.; Suzuki, M.; Shimada, T.; Watanabe, K.; Hirokawa, Y.; Furugori, T.; Nagahara, T. Synthesis and conformational analysis of a non-amidine factor Xa inhibitor that incorporates 5-methyl-4,5,6,7-tetrahydrothiazolo[5,4,c]pyridine as S4 binding element. J. Med. Chem. 2004, 47, 5167–5182. (234) Jung, F. H.; Pasquet, G.; Lambert-van der Brempt, C.; Lohmann, J.-J. M.; Warin, N.; Renaud, F.; Germain, H.; De Savi, C.; Roberts, N.; Johnson, T.; Dousson, C.; Hill, G. B.; Mortlock, A. A.; Heron, N.; Wilkinson, R. W.; Wedge, S. R.; Heaton, S. P.; Odedra, R.; Keen, N. J.; Green, S.; Brown, E.; Thompson, K.; Brightwell, S. Discovery of novel and potent thiazoloquinazolines as selective aurora A and B kinase inhibitors. J. Med. Chem. 2006, 49, 955–970. (235) Goldstein, B. M.; Takusagawa, F.; Berman, H. M.; Srivastava, P. C.; Robins, R. K. Structural studies of a new antitumor agent: tiazofurin and its inactive analogs. J. Am. Chem. Soc. 1983, 105, 7416–7422. (236) Li, H.; Hallows, W. A.; Punzi, J. S.; Marquez, V. E.; Carrell, H. L.; Pankiewicz, K. W.; Watanabe, K. A.; Goldstein, B. M. Crystallographic studies of two alcohol dehydrogenase-bound analogs of thiazole-4-carboxamide adenine dinucleotide (TAD), the active anabolite of the antitumor agent tiazofurin. Biochemistry 1994, 33, 23–32. (237) Goldstein, B. M.; Li, H.; Hallows, W. H.; Langs, D. A.; Franchetti, P.; Cappellacci, L.; Grifantini, M. C-Glycosyl bond conformation in oxazofurin: crystallographic and computational studies of the oxazole analog of tiazofurin. J. Med. Chem. 1994, 37, 1684–1688. (238) Franchetti, P.; Cappellacci, L.; Grifantini, M.; Barzi, A.; Nocentini, G.; Yang, H.; O’Connor, A.; Jayaram, H. N.; Carrell, C.; Goldstein, B. M. Furanfurin and thiophenfurin: two novel tiazofurin analogs. Synthesis, structure, antitumor activity, and interactions with inosine monophosphate dehydrogenase. J. Med. Chem. 1995, 38, 3829–3837. (239) Nagao, Y.; Hirata, T.; Goto, S.; Sano, S.; Kakehi, A.; Iizuka, K.; Shiro, M. Intramolecular nonbonded S 3 3 3 O interaction recognized in (acylimino)thiadazoline derivatives as angiotensin II receptor antagonists and related compounds. J. Am. Chem. Soc. 1998, 120, 3104–3110. (240) Hayashi, K.; Ogawa, S.; Sano, S.; Shiro, M.; Yamaguchi, K.; Sei, Y.; Nagao, Y. Intramolecular nonbonded S 3 3 3 O interaction in rabeprazole. Chem. Pharm. Bull. 2008, 56, 802–806. (241) Bradamante, S.; Pagani, G. A. Benzyl and heteroarylmethyl carbanions: structure and substituent effects. Adv. Carbanion Chem. 1996, 2, 189–263. (242) Abbotto, A.; Bradamante, S.; Pagani, G. A. Charge mapping in carbanions. Weak charge demand of the cyano group as assessed from a 13C-NMR study of carbanions of R-activated acetonitriles and phenylacetonitriles: breakdown of a myth. J. Org. Chem. 1993, 58, 449– 455. (243) Abbotto, A.; Bradamante, S.; Pagani, G. A. Diheteroarylmethanes. 5. E-Z isomerism of carbanions substituted by 1,3-azoles: 13 C and 15N-charge/shift relationships as source for mapping charge and PERSPECTIVE ranking the electron-withdrawing power of heterocycles. J. Org. Chem. 1996, 61, 1761–1769. (244) Abbotto, A.; Bradamante, S.; Facchetti, A.; Pagani, G. A. Diheteroarylmethanes. 8. Mapping charge and electron-withdrawing power of the 1,2,4-triazol-5-yl substituent. J. Org. Chem. 1999, 64, 6756– 6763. (245) Hedstrom, L. Serine protease mechanism and specificity. Chem. Rev. 2002, 102, 4501–4523. (246) Edwards, P. D.; Meyer, E. F., Jr.; Vijayalakshmi, J.; Tuthill, P. A.; Andisik, D. A.; Gomes, B.; Strimplerg, A. Elastase inhibitors, the peptidyl R-ketobenzoxazoles, and the X-ray crystal structure of the covalent complex between porcine pancreatic elastase and Ac-Ala-ProVal-2-benzoxazole. J. Am. Chem. Soc. 1992, 114, 1854–1863. (247) Edwards, P. D.; Wolanin, D. J.; Andisik, D. A.; David, M. W. Peptidyl R-ketoheterocyclic inhibitors of human neutrophil elastase. 2. Effect of varying the heterocyclic ring on in vitro potency. J. Med. Chem. 1995, 38, 76–85. (248) Edwards, P. D.; Zottola, M. A.; Davis, M.; Williams, J.; Tuthill, P. A. Peptidyl R-ketoheterocyclic inhibitors of human neutrophil elastase. 3. In vitro and in vivo potency of a series of peptidyl R-ketobenzoxazoles. J. Med. Chem. 1995, 38, 3972–3982. (249) Ohmoto, K.; Yamamoto, T.; Horiuchi, T.; Imanishi, H.; Odagaki, Y.; Kawabata, K.; Sekioka, T.; Hirota, Y.; Matsuoka, S.; Nakai, H.; Toda, M.; Cheronis, J. C.; Spruce, L. W.; Gyorkos, A.; Wieczorek, M. Design and synthesis of new orally active nonpeptidic inhibitors of human neutrophil elastase. J. Med. Chem. 2000, 43, 4927–4929. (250) Ohmoto, K.; Yamamoto, T.; Okuma, M.; Horiuchi, T.; Imanishi, Hi.; Odagaki, Y.; Kawabata, K.; Sekioka, T.; Hirota, Y.; Matsuoka, S.; Nakai, H.; Toda, M.; Cheronis, J. C.; Spruce, L. W.; Gyorkos, A.; Wieczorek, M. Development of orally active nonpeptidic inhibitors of human neutrophil elastase. J. Med. Chem. 2001, 44, 1268–1285. (251) Costanzo, M. J.; Almond, H. R., Jr; Hecker, L. R.; Schott, M. R.; Yabut, S. C.; Zhang, H.-C.; Andrade-Gordon, P.; Corcoran, T. W.; Giardino, E. C.; Kauffman, J. A.; Lewis, J. M.; de Garavilla, L.; Haertlein, B. J.; Maryanoff, B. E. In-depth study of tripeptide-based R-ketoheterocycles as inhibitors of thrombin. Effective utilization of the S10 subsite and its implications to structure-based drug design. J. Med. Chem. 2005, 48, 1984–2008. (252) Maryanoff, B. E.; Costanzo, M. J. Inhibitors of proteases and amide hydrolases that employ R-ketoheterocycles as a key enabling functionality. Bioorg. Med. Chem. 2008, 16, 1562–1595. (253) Romero, F. A.; Hwang, I.; Boger, D. L. Delineation of a fundamental R-ketoheterocycle substituent effect for use in the design of enzyme inhibitors. J. Am. Chem. Soc. 2006, 128, 14004–14005. (254) Mileni, M.; Garfunkle, J.; DeMartino, J. K.; Cravatt, B. F.; Boger, D. L.; Stevens, R. C. Binding and inactivation mechanism of a humanized fatty acid amide hydrolase by R-ketoheterocycle inhibitors revealed from cocrystal structures. J. Am. Chem. Soc. 2009, 131, 10497– 10506. (255) Hansch, C.; Leo, A.; Unger, S. H.; Kim, K. H.; Nikaitani, D.; Lien, E. J. Aromatic substituent constants for structure-activity correlations. J. Med. Chem. 1973, 16, 1207–1216. (256) Taylor, R.; Mullaley, A.; Mullier, G. W. Use of crystallographic data in searching for isosteric replacements: composite crystal-field environments of nitro and carbonyl groups. Pestic. Sci. 1990, 29, 197–213. (257) Firestine, S. M.; Davisson, V. J. A tight binding inhibitor of 5-aminoimidazole ribonucleotide carboxylase. J. Med. Chem. 1993, 36, 3484–3486. (258) Gnewuch, C. T.; Friedman, H. L. Pyridine isosteres of the β-adrenergic antagonists, 2-(p-nitrophenyl)-1-isopropylamino-2-ethanol and 3-(p-nitrophenoxy)-1-isopropylamino-2-propanol. J. Med. Chem. 1972, 15, 1321–1324. (259) Sang, X.; Du, K.; Kadow, J. F.; Langley, D. R.; Vite, G. D.; Vyas, D. M.; Wittman, M. D.; Wong, T. W. Synthesis and SAR of Dithiazole HER Kinase Inhibitors. Presented at the 227th National Meeting of the American Chemical Society, Anaheim, CA, United States, March 28-April 1, 2004; MEDI-44. 2587 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry (260) Li, F.; Chordia, M. D.; Huang, T.; Macdonald, T. L. In vitro nimesulide studies toward understanding idiosyncratic hepatotoxicity: diiminoquinone formation and conjugation. Chem. Res. Toxicol. 2009, 22, 72–80. (261) Julemont, F.; de Leval, X.; Michaux, C.; Damas, J.; Charlier, C.; Durant, F.; Pirotte, B.; Dogne, J.-M. Spectral and crystallographic study of pyridinic analogues of nimesulide: determination of the active form of methanesulfonamides as COX-2 selective inhibitors. J. Med. Chem. 2002, 45, 5182–5185. (262) Renard, J.-F.; Arslan, D.; Garbacki, N.; Pirotte, B.; de Leval, X. Pyridine analogues of nimesulide: design, synthesis, and in vitro and in vivo pharmacological evaluation as promising cyclooxygenase 1 and 2 inhibitors. J. Med. Chem. 2009, 52, 5864–5871. (263) Dhar, T. G. M.; Nagarathnam, D.; Marzabadi, M. R.; Lagu, B.; Wong, W. C.; Chiu, G.; Tyagarajan, S.; Miao, S. W.; Zhang, F.; Sun, W.; Tian, D.; Shen, Q.; Zhang, J.; Wetzel, J. M.; Forray, C.; Chang, R. S. L.; Broten, T. P.; Schorn, T. W.; Chen, T. B.; O’Malley, S.; Ransom, R.; Schneck, K.; Bendesky, R.; Harrell, C. M.; Vyas, K. P.; Zhang, K.; Gilbert, J.; Pettibone, D. J.; Patane, M. A.; Bock, M. G.; Freidinger, R. M.; Gluchowski, C. Design and synthesis of Novel R1a adrenoceptor-selective antagonists. 2. Approaches to eliminate opioid agonist metabolites via modification of linker and 4-methoxycarbonyl-4-phenylpiperidine moiety. J. Med. Chem. 1999, 42, 4778–4793. (264) Lagu, B.; Tian, D.; Nagarathnam, D.; Marzabadi, M. R.; Wong, W. C.; Miao, S. W.; Zhang, F.; Sun, W.; Chiu, G.; Fang, J.; Forray, C.; Chang, R. S. L.; Ransom, R. W.; Chen, T. B.; O’Malley, S.; Zhang, K.; Vyas, K. P.; Gluchowski, C. Design and synthesis of novel R1a adrenoceptor-selective antagonists. 3. Approaches to eliminate opioid agonist metabolites by using substituted phenylpiperazine side chains. J. Med. Chem. 1999, 42, 4794–4803. (265) Leriche, C.; He, X.; Chang, C.-w.T.; Liu, H.-w. Reversal of the apparent regiospecificity of NAD(P)H-dependent hydride transfer: the properties of the difluoromethylene group, a carbonyl mimic. J. Am. Chem. Soc. 2003, 125, 6348–6349. (266) Vandyck, K.; Cummings, M. D.; Nyanguile, O.; Boutton, C. W.; Vendeville, S.; McGowan, D.; Devogelaere, B.; Amssoms, K.; Last, S.; Rombauts, K.; Tahri, A.; Lory, P.; Hu, L.; Beauchamp, D. A.; Simmen, K.; Raboisson, P. Structure-based design of a benzodiazepine scaffold yields a potent allosteric inhibitor of hepatitis C NS5B RNA polymerase. J. Med. Chem. 2009, 52, 4099–4102. (267) Wuitschik, G.; Rogers-Evans, M.; Buckl, A.; Bernasconi, M.; Marki, M.; Godel, T.; Fischer, H.; Wagner, B.; Parrilla, I.; Schuler, F.; Schneider, J.; Alker, A.; Schweizer, W. B.; M€uller, K; Carreira, E. M. Spirocyclic oxetanes: synthesis and properties. Angew Chem., Int. Ed. 2008, 47, 4512–4515. (268) Berthelot, M.; Besseau, F.; Laurence, C. The hydrogen-bond basicity pKHB scale of peroxides and ethers. Eur. J. Org. Chem. 1998, 925–931. (269) Besseau, F.; Lucon, M.; Laurence, C.; Berthelot, M. Hydrogen-bond basicity pKHB scale of aldehydes and ketones. J. Chem. Soc., Perkin Trans. 2 1998, 101–108. (270) Parlow, J. J.; Kurumbail, R. G.; Stegeman, R. A.; Stevens, A. M.; Stallings, W. C.; South, M. S. Design, synthesis, and crystal structure of selective 2-pyridone tissue factor VIIa inhibitors. J. Med. Chem. 2003, 46, 4696–4701. (271) Parlow, J. J.; Kurumbail, R. G.; Stegeman, R. A.; Stevens, A. M.; Stallings, W. C.; South, M. S. Synthesis and X-ray crystal structures of substituted fluorobenzene and benzoquinone inhibitors of the tissue factor VIIa complex. Bioorg. Med. Chem. Lett. 2003, 13, 3721–3725. (272) Lee, L.; Kreutter, K. D.; Pan, W.; Crysler, C.; Spurlino, J.; Player, M. R.; Tomczuk, B.; Lu, T. 2-(2-Chloro-6-fluorophenyl)acetamides as potent thrombin inhibitors. Bioorg. Med. Chem. Lett. 2007, 17, 6266–6269. (273) Kreutter, K. D.; Lu, T.; Lee, L.; Giardino, E. C.; Patel, S.; Huang, H.; Xu, G.; Fitzgerald, M.; Haertlein, B. J.; Mohan, V.; Crysler, C.; Eisennagel, S.; Dasgupta, M.; McMillan, M.; Spurlino, J. C.; Huebert, N. D.; Maryanoff, B. E.; Tomczuk, B. E.; Damiano, B. P.; Player, M. R. Orally efficacious thrombin inhibitors with cyanofluorophenylace- PERSPECTIVE tamide as the P2 motif. Bioorg. Med. Chem. Lett. 2008, 18, 2865– 2870. (274) Dubowchik, G. M.; Vrudhula, V. M.; Dasgupta, B.; Ditta, J.; Chen, T.; Sheriff, S.; Sipman, K.; Witmer, M.; Tredup, J.; Vyas, D. M.; Verdoorn, T. A.; Bollini, S.; Vinitsky, A. 2-Aryl-2,2-difluoroacetamide FKBP12 ligands: synthesis and X-ray structural studies. Org. Lett. 2001, 3, 3987–3990. (275) Watjen, F.; Baker, R.; Engelstoff, M.; Herbert, R.; MacLeod, A.; Knight, A.; Merchant, K.; Moseley, J.; Saunders, J.; Swain, C. J.; Wong, E.; Springer, J. P. Novel benzodiazepine receptor partial agonists: oxadiazolylimidazobenzodiazepines. J. Med. Chem. 1989, 32, 2282–2291. (276) Saunders, J.; Cassidy, M.; Freedman, S. B.; Harley, E. A.; Iversen, L. L.; Kneen, C.; MacLeod, A. M.; Merchant, K. J.; Snow, R. J.; Baker, R. Novel quinuclidine-based ligands for the muscarinic cholinergic receptor. J. Med. Chem. 1990, 33, 1128–1138. (277) Sani, M.; Volonterio, A.; Zanda, M. The trifluoroethylamine function as peptide bond replacement. ChemMedChem 2007, 2, 1693–1700. (278) Volonterio, A.; Bellosta, S.; Bravin, F.; Bellucci, M. C.; Bruche, L.; Colombo, G.; Malpezzi, L.; Mazzini, S.; Meille, S. V.; Meli, M.; Ramirez de Arellano, C.; Zanda, M. Synthesis, structure and conformation of partially-modified retro- and retro-inverso Ψ[NHCH(CF3)]Gly peptides. Chem.-Eur. J. 2003, 9, 4510–4522. (279) Zanda, M. Trifluoromethyl group: an effective xenobiotic function for peptide backbone modification. New J. Chem. 2004, 28, 1401–1411. (280) Molteni, M.; Pesenti, C.; Sani, M.; Volonterio, A.; Zanda, M. Fluorinated peptidomimetics: synthesis, conformational and biological features. J. Fluorine Chem. 2004, 125, 1735–1743. (281) Binkert, C.; Frigerio, M.; Jones, A.; Meyer, S.; Pesenti, C.; Prade, L.; Viani, F.; Zanda, M. Replacement of isobutyl by trifluoromethyl in pepstatin A selectively affects inhibition of aspartic proteinases. ChemBioChem 2006, 7, 181–186. (282) Molteni, M.; Bellucci, M. C.; Bigotti, S.; Mazzini, S.; Volonterio, A.; Zanda, M. Ψ[CH(CF3)NH]Gly-peptides: synthesis and conformation analysis. Org. Biomol. Chem. 2009, 7, 2286–2296. (283) Sinisi, R.; Ghilardi, A.; Ruiu, S.; Lazzari, P.; Malpezzi, L.; Sani, M.; Pani, L.; Zanda, M. Synthesis and in vitro evaluation of trifluoroethylamine analogues of enkephalins. ChemMedChem 2009, 4, 1416– 1420. (284) Black, W. C.; Bayly, C. I.; Davis, D. E.; Desmarais, S.; Falgueyret, J.-P.; Leger, S.; Li, C. S.; Masse, F.; McKay, D. J.; Palmer, J. T.; Percival, M. D.; Robichaud, J.; Tsou, N.; Zamboni, R. Trifluoroethylamines as amide isosteres in inhibitors of cathepsin K. Bioorg. Med. Chem. Lett. 2005, 15, 4741–4744. (285) Gauthier, J. Y.; Chauret, N.; Cromlish, W.; Desmarais, S.; Duong, L. T.; Falgueyret, J.-P.; Kimmel, D. B.; Lamontagne, S.; Leger, S.; LeRiche, T.; Li, C. S.; Masse, F.; McKay, D. J.; Nicoll-Griffith, D. A.; Oballa, R. M.; Palmer, J. T.; Percival, M. D.; Riendeau, D.; Robichaud, J.; Rodan, G. A.; Rodan, S. B.; Seto, C.; Therien, M.; Truong, V.-L.; Venuti, M. C.; Wesolowski, G.; Young, R. N.; Zamboni, R.; Black, W. C. The discovery of odanacatib (MK-0822), a selective inhibitor of cathepsin K. Bioorg. Med. Chem. Lett. 2008, 18, 923–928. (286) Holsinger, L. J.; Elrod, K.; Link, J. O.; Graupe, M.; Kim, I. J. Preparation of Peptides That Inhibit Protease Cathepsin S and HCV Replication. World Patent Application WO-2009/055467 A2, 2009. (287) Eastwood, P.; Gonzalez, J.; Paredes, S.; Fonquerna, S.; Cardus, A.; Alonso, J. A.; Nueda, A.; Domenech, T.; Reinoso, R. F.; Vidal, B. Discovery of potent and selective bicyclic A2B adenosine receptor antagonists via bioisosteric amide replacement. Bioorg. Med. Chem. Lett. 2010, 20, 1634–1637. (288) Ulrich, R. G.; Bacon, J. A.; Brass, E. P.; Cramer, C. T.; Petrella, D. K.; Sun, E. L. Metabolic, idiosyncratic toxicity of drugs: overview of the hepatic toxicity induced by the anxiolytic, panadiplon. Chem.-Biol. Interact. 2001, 134, 251–270. (289) Ghosh, A. K. Harnessing nature’s insight: design of aspartyl protease inhibitors from treatment of drug-resistant HIV to Alzheimer’s disease. J. Med. Chem. 2008, 52, 2163–2176. 2588 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry (290) Ghosh, A. K.; Chapsal, B. D.; Weber, I. T.; Mitsuya, H. Inhibitors targeting protein backbone: an effective strategy for combating drug resistance. Acc. Chem. Res. 2008, 41, 78–86. (291) Wang, T.; Zhang, Z.; Wallace, O. B.; Deshpande, M.; Fang, H.; Yang, Z.; Zadjura, L. M.; Tweedie, D. L.; Huang, S.; Zhao, F.; Ranadive, S.; Robinson, B. S.; Gong, Y.-F.; Ricarrdi, K.; Spicer, T. P.; Deminie, C.; Rose, R.; Wang, H.-G. H.; Blair, W. S.; Shi, P.-Y.; Lin, P.-f.; Colonno, R. J.; Meanwell, N. A. Discovery of 4-benzoyl-1-[(4-methoxy-1Hpyrrolo[2,3-b]pyridin-3-yl)oxoacetyl]-2-(R)-methylpiperazine (BMS378806): a novel HIV-1 attachment inhibitor that interferes with CD4gp120 interactions. J. Med. Chem. 2003, 46, 4236–4239. (292) Lu, R.-J.; Tucker, J. A.; Zinevitch, T.; Kirichenko, O.; Konoplev, V.; Kuznetsova, S.; Sviridov, S.; Pickens, J.; Tandel, S.; Brahmachary, E.; Yang, Y.; Wang, J.; Freel, S.; Fisher, S.; Sullivan, A.; Zhou, J.; Stanfield-Oakley, S.; Greenberg, M.; Bolognesi, D.; Bray, B.; Koszalka, B.; Jeffs, P.; Khasanov, A.; Ma, Y.-A.; Jeffries, C.; Liu, C.; Proskurina, T.; Zhu, T.; Chucholowski, A.; Li, R.; Sexton, C. Design and synthesis of human immunodeficiency virus entry inhibitors: sulfonamide as an isostere for the R-ketoamide group. J. Med. Chem. 2007, 50, 6535–6544. (293) Lu, R.-J.; Tucker, J. A.; Pickens, J.; Ma, Y.-A.; Zinevitch, T.; Kirichenko, O.; Konoplev, V.; Kuznetsova, S.; Sviridov, S.; Brahmachary, E.; Khasanov, A.; Mikel, C.; Yang, Y.; Liu, C.; Wang, J.; Freel, S.; Fisher, S.; Sullivan, A.; Zhou, J.; Stanfield-Oakley, S.; Baker, B.; Sailstad, J.; Greenberg, M.; Bolognesi, D.; Bray, B.; Koszalka, B.; Jeffs, P.; Jeffries, C.; Chucholowski, A.; Sexton, C. Heterobiaryl human immunodeficiency virus entry inhibitors. J. Med. Chem. 2009, 52, 4481–4487. (294) Durant, G. J.; Emmett, J. C.; Ganellin, C. R.; Miles, P. D.; Parsons, M. E.; Prain, H. D.; White, G. R. Cyanoguanidine-thiourea equivalence in the development of the histamine H2-receptor antagonist, cimetidine. J. Med. Chem. 1977, 20, 901–906. (295) Lumma, W. C., Jr.; Anderson, P. S.; Baldwin, J. J.; Bolhofer, W. A.; Habecker, C. N.; Hirshfield, J. M.; Pietruszkiewicz, A. M.; Randall, W. C.; Torchiana, M. L.; Britcher, S. F.; Clineschmidt, B. V.; Denny, G. H.; Hirschmann, R.; Hoffman, J. M.; Phillips, B. T.; Streeter, K. B. Inhibitors of gastric acid secretion: 3,4-diamino-1,2,5-thiadiazole 1-oxides and 1,1-dioxides as urea equivalents in a series of histamine H2-receptor antagonists. J. Med. Chem. 1982, 25, 207–210. (296) Algieri, A. A.; Luke, G. M.; Standridge, R. T.; Brown, M.; Partyka, R. A.; Crenshaw, R. R. 1,2,5-Thiadiazole 1-oxide and 1,1dioxide derivatives. a new class of potent histamine H2-receptor antagonists. J. Med. Chem. 1982, 25, 210–212. (297) Gilbert, A. M.; Antane, M. M.; Argentieri, T. M.; Butera, J. A.; Francisco, G. D.; Freeden, C.; Gundersen, E. G.; Graceffa, R. F.; Herbst, D.; Hirth, B. H.; Lennox, J. R.; McFarlane, G.; Norton, N. W.; Quagliato, D.; Sheldon, J. H.; Warga, D.; Wojdan, A.; Woods, M. Design and SAR of novel potassium channel openers targeted for urge urinary incontinence. 2. Selective and potent benzylamino cyclobutenediones. J. Med. Chem. 2000, 43, 1203–1214. (298) Ohnmacht, C. J.; Russell, K.; Empfield, J. R.; Frank, C. A.; Gibson, K. H.; Mayhugh, D. R.; McLaren, F. M.; Shapiro, H. S.; Brown, F. J.; Trainor, D. A.; Ceccarelli, C.; Lin, M. M.; Masek, B. B.; Forst, J. M.; Harris, R. J.; Hulsizer, J. M.; Lewis, J. J.; Silverman, S. M.; Smith, R. W.; Warwick, P. J.; Kau, S. T.; Chun, A. L.; Grant, T. L.; Howe, B. B.; Li, J. H.; Trivedi, S.; Halterman, T. J.; Yochim, C.; Dyroff, M. C.; Kirkland, M.; Neilson, K. L. N-Aryl-3,3,3-trifluoro-2-hydroxy-2-methylpropanamides: KATP potassium channel openers. Modifications on the western region. J. Med. Chem. 1996, 39, 4592–4601. (299) Merritt, J. R.; Rokosz, L. L.; Nelson, K. H.; Kaiser, B.; Wang, W.; Stauffer, T. M.; Ozgur, L. E.; Schilling, A.; Li, G.; Baldwin, J. J.; Taveras, A. G.; Dwyer, M. P.; Chao, J. Synthesis and structure-activity relationships of 3,4-diaminocyclobut-3-ene-1,2-dione CXCR2 antagonists. Bioorg. Med. Chem. Lett. 2006, 16, 4107–4110. (300) Dwyer, M. P.; Yu, Y.; Chao, J.; Aki, C.; Chao, J.; Biju, P.; Girijavallabhan, V.; Rindgen, D.; Bond, R.; Mayer-Ezel, R.; Jakway, J.; Hipkin, R. W.; Fossetta, J.; Gonsiorek, W.; Bian, H.; Fan, X.; Terminelli, C.; Fine, J.; Lundell, D.; Merritt, J. R.; Rokosz, L. L.; Kaiser, B.; Li, G.; Wang, W.; Stauffer, T.; Ozgur, L.; Baldwin, J.; Taveras, A. G. PERSPECTIVE Discovery of 2-hydroxy-N,N-dimethyl-3-{2-[[(R)-1-(5-methylfuran-2yl)propyl]amino]-3,4-dioxocyclobut-1-enylamino}benzamide (SCH 527123): a potent, orally bioavailable CXCR2/CXCR1 receptor antagonist. J. Med. Chem. 2006, 49, 7603–7606. (301) Lovering, F.; Kirincich, S.; Wanga, W.; Combs, K.; Resnick, L.; Sabalski, J. E.; Butera, J.; Liu, J.; Parris, K.; Telliez, J. B. Identification and SAR of squarate inhibitors of mitogen-activated protein kinase-activated protein kinase 2 (MK-2). Bioorg. Med. Chem. 2009, 17, 3342–3351. (302) Porter, J. R.; Archibald, S. C.; Childs, K.; Critchley, D.; Head, J. C.; Linsley, J. M.; Parton, T. A. H.; Robinson, M. K.; Shock, A.; Taylor, R. J.; Warrellow, G. J.; Alexander, R. P.; Langham, B. Squaric acid derivatives as VLA-4 integrin antagonists. Bioorg. Med. Chem. Lett. 2002, 12, 1051–1054. (303) Malerich, J. P.; Hagihara, K.; Rawal, V. H. Chiral squaramide derivatives are excellent hydrogen bond donor catalysts. J. Am. Chem. Soc. 2008, 130, 14416–14417. (304) Shi, Y.; Zhang, J.; Stein, P. D.; Shi, M.; O’Connor, S. P.; Bisaha, S. N.; Li, C.; Atwal, K. S.; Bisacchi, G. S.; Sitkoff, D.; Pudzianowski, A. T.; Liu, E. C.; Hartl, K. S.; Seiler, S. M.; Youssef, S.; Steinbacher, T. E.; Schumacher, W. A.; Rendina, A. R.; Bozarth, J. M.; Peterson, T. L.; Zhang, G.; Zahler, R. Ketene aminal-based lactam derivatives as a novel class of orally active FXa inhibitors. Bioorg. Med. Chem. Lett. 2004, 15, 5453–5458. (305) Peterlin-Masic, L.; Kikelj, D. Arginine mimetics. Tetrahedron 2001, 57, 7073–7105. (306) Peterlin-Masic, L. Arginine mimetic structure in biologically active antagonists and inhibitors. Curr. Med. Chem. 2006, 13, 3627– 3648. (307) Ghorai, P.; Kraus, A.; Keller, M.; Gotte, C.; Igel, P.; Schneider, E.; Schnell, D.; Bernhardt, G.; Dove, S.; Zabel, M.; Elz, S.; Seifert, R.; Buschauer, A. Acylguanidines as bioisosteres of guanidines: NG-acylated imidazolylpropylguanidines, a new class of histamine H2 receptor agonists. J. Med. Chem. 2008, 51, 7193–7204. (308) Kraus, A.; Ghorai, P.; Birnkammer, T.; Schnell, D.; Elz, S.; Seifert, R.; Dove, S.; Bernhardt, G.; Buschauer, A. NG-Acylated aminothiazolylpropylguanidines as potent and selective histamine H2 receptor agonists. ChemMedChem 2009, 4, 232–240. (309) Tomczuk, B.; Lu, T.; Soll, R. M.; Fedde, C.; Wang, A.; Murphy, L.; Crysler, C.; Dasgupta, M.; Eisennagel, S.; Spurlino, J.; Bone, R. Oxyguanidines: application to non-peptidic phenylbased thrombin inhibitors. Bioorg. Med. Chem. Lett. 2003, 13, 1495– 1498. (310) Lu, T.; Markotan, T.; Coppo, F.; Tomczuk, B.; Crysler, C.; Eisennagel, S.; Spurlino, J.; Gremminger, L.; Soll, R. M.; Giardino, E. C.; Bone, R. Oxyguanidines. Part 2: Discovery of a novel orally active thrombin inhibitor through structure-based drug design and parallel synthesis. Bioorg. Med. Chem. Lett. 2004, 14, 3727–3731. (311) Lu, T.; Markotan, T.; Ballentine, S. K.; Giardino, E. C.; Spurlino, J.; Brown, K.; Maryanoff, B. E.; Tomczuk, B. E.; Damiano, B. P.; Shukla, U.; End, D.; Andrade-Gordon, P.; Bone, R. F.; Player, M. R. Discovery and clinical evaluation of 1-{N-[2-(amidinoaminooxy)ethyl]amino}carbonylmethyl-6-methyl-3-[2,2-difluoro-2-phenylethylamino]pyrazinone (RWJ-671818), a thrombin inhibitor with an oxyguanidine P1 motif. J. Med. Chem. 2010, 53, 1843–1856. (312) Pinto, D. J. P.; Smallheer, J. M.; Cheney, D. L.; Knabb, R. M.; Wexler, R. R. Factor Xa inhibitors: next-generation antithrombotic agents. J. Med. Chem. 2010, 53, 6243–6274. (313) Lam, P. Y. S.; Clark, C. G.; Li, R.; Pinto, D. J. P.; Orwat, M. J.; Galemmo, R. A.; Fevig, J. M.; Teleha, C. A.; Alexander, R. S.; Smallwood, A. M.; Rossi, K. A.; Wright, M. R.; Bai, S. A.; He, K.; Luettgen, J. M.; Wong, P. C.; Knabb, R. M.; Wexler, R. R. Structure-based design of novel guanidine/benzamidine mimics: potent and orally bioavailable factor Xa inhibitors as novel anticoagulants. J. Med. Chem. 2003, 46, 4405– 4418. (314) Mederski, W. W. K. R.; Dorsch, D.; Anzali, S.; Gleitz, J.; Cezanne, B.; Tsaklakidis, C. Halothiophene benzimidazoles as P1 surrogates of inhibitors of blood coagulation factor Xa. Bioorg. Med. Chem. Lett. 2004, 14, 3763–3769. 2589 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry (315) Tucker, T. J.; Brady, S. F.; Lumma, W. C.; Lewis, S. D.; Gardell, S. J.; Naylor-Olsen, A. M.; Yan, Y.; Sisko, J. T.; Stauffer, K. J.; Lucas, B. J.; Lynch, J. J.; Cook, J. J.; Stranieri, M. T.; Holahan, M. A.; Lyle, E. A.; Baskin, E. P.; Chen, I.-W.; Dancheck, K. B.; Krueger, J. A.; Cooper, C. M.; Vacca, J. P. Design and synthesis of a series of potent and orally bioavailable noncovalent thrombin inhibitors that utilize nonbasic groups in the P1 position. J. Med. Chem. 1998, 41, 3210–3219. (316) Lee, C.-W.; Cao, H.; Ichiyama, K.; Rana, T. M. Design and synthesis of a novel peptidomimetic inhibitor of HIV-1 Tat-TAR interactions: squaryldiamide as a new potential bioisostere of unsubstituted guanidine. Bioorg. Med. Chem. Lett. 2005, 15, 4243–4246. (317) Rye, C. S.; Baell, J. B. Phosphate isosteres in medicinal chemistry. Curr Med. Chem. 2005, 12, 3127–3141. (318) Romanenko, V. D.; Kukhar, V. P. Fluorinated phosphonates: synthesis and biomedical application. Chem. Rev. 2006, 106, 3868–3935. (319) Blackburn, G. M.; Kent, D. E. A novel synthesis of R- and γ-fluoroalkylphosphonates. Chem. Commun. 1981, 511–513. (320) Blackburn, G. M.; England, D. A.; Kolkmann, F. Monofluoroand difluoro-methylenebisphosphonic acids: isopolar analogues of pyrophosphoric acid. Chem. Commun. 1981, 930–932. (321) Smyth, M. S.; Ford, H., Jr.; Burke, T. R., Jr. A general method for the preparation of benzylic R,R-difluorophosphonic acids; nonhydrolyzable mimetics of phosphotyrosine. Tetrahedron Lett. 1992, 33, 4137–4140. (322) Combs, A. P. Structure-based drug design of new leads for phosphatase research. IDrugs 2007, 10, 112–115. (323) Combs, A. P. Recent advances in the discovery of competitive protein tyrosine phosphatase 1B inhibitors for the treatment of diabetes, obesity, and cancer. J. Med. Chem. 2010, 53, 2333–2344. (324) Combs, A. P.; Yue, E. W.; Bower, M.; Ala, P. J.; Wayland, B.; Douty, B.; Takvorian, A.; Polam, P.; Wasserman, Z.; Zhu, W.; Crawley, M. L.; Pruitt, J.; Sparks, R.; Glass, B.; Modi, D.; McLaughlin, E.; Bostrom, L.; Li, M.; Galya, L.; Blom, K.; Hillman, M.; Gonneville, L.; Reid, B. G.; Wei, M.; Becker-Pasha, M.; Klabe, R.; Huber, R.; Li, Y.; Hollis, G.; Burn, T. C.; Wynn, R.; Liu, P.; Metcalf, B. Structure-based design and discovery of protein tyrosine phosphatase inhibitors incorporating novel isothiazolidinone heterocyclic phosphotyrosine mimetics. J. Med. Chem. 2005, 48, 6544–6548. (325) Combs, A. P.; Zhu, W.; Crawley, M. L.; Glass, B.; Polam, P.; Sparks, R. B.; Modi, D.; Takvorian, A.; McLaughlin, E.; Yue, E. W.; Wasserman, Z.; Bower, M.; Wei, M.; Rupar, M.; Ala, P. J.; Reid, B. M.; Ellis, D.; Gonneville, L.; Emm, T.; Taylor, N.; Yeleswaram, S.; Li, Y.; Wynn, R.; Burn, T. C.; Hollis, G.; Liu, P. C. C.; Metcalf, B. Potent benzimidazole sulfonamide protein tyrosine phosphatase 1B inhibitors containing the heterocyclic (S)-isothiazolidinone phosphotyrosine mimetic. J. Med. Chem. 2006, 49, 3774–3789. (326) Black, E.; Breed, J.; Breeze, A. L.; Embrey, K.; Garcia, R.; Gero, T. W.; Godfrey, L.; Kenny, P. W.; Morley, A. D.; Minshull, C. A.; Pannifer, A. D.; Read, J.; Rees, A.; Russell, D. J.; Toader, D.; Tucker, J. Structure-based design of protein tyrosine phosphatase-1B inhibitors. Bioorg. Med. Chem. Lett. 2005, 15, 2503–2507. (327) Muthyala, R. S.; Subramaniam, G.; Todaro, L. The use of squaric acid as a scaffold for cofacial phenyl rings. Org. Lett. 2004, 6, 4663–4665. (328) Sato, K.; Seio, K.; Sekine, M. Squaryl group as a new mimic of phosphate group in modified oligodeoxynucleotides: synthesis and properties of new oligodeoxynucleotide analogues containing an internucleotidic squaryldiamide linkage. J. Am. Chem. Soc. 2002, 124, 12715– 12724. (329) Seio, K.; Miyashita, T.; Sato, K.; Sekine, M. Synthesis and properties of new nucleotide analogues possessing squaramide moieties as new phosphate isosteres. Eur. J. Org. Chem. 2005, 5163–5170. (330) Niewiadomski, S.; Beebeejaun, Z.; Denton, H.; Smith, T. K.; Morris, R. J.; Wagner, G. K. Rationally designed squaryldiamides: a novel class of sugar-nucleotide mimics? Org. Biomol. Chem. 2010, 8, 3488–3499. (331) Savarino, A. A historical sketch of the discovery and development of HIV-1 integrase inhibitors. Expert Opin. Invest. Drugs 2006, 15, 1507–1522. PERSPECTIVE (332) Johns, B. A.; Svolto, A. C. Advances in two-metal chelation inhibitors of HIV integrase. Expert Opin. Ther. Pat. 2008, 18, 1225–1237. (333) Kirschberg, T. A.; Balakrishnan, M.; Squires, N. H.; Barnes, T.; Brendza, K. M.; Chen, X.; Eisenberg, E. J.; Jin, W.; Kutty, N.; Leavitt, S.; Liclican, A.; Liu, Q.; Liu, X.; Mak, J.; Perry, J. K.; Wang, M.; Watkins, W. J.; Lansdon, E. B. RNase H active site inhibitors of human immunodeficiency virus type 1 reverse transcriptase: design, biochemical activity, and structural information. J. Med. Chem. 2009, 52, 5781–5784. (334) Powdrill, M. H.; Deval, J.; Narjes, F.; De Francesco, R.; G€otte, M. Mechanism of hepatitis C virus RNA polymerase inhibition with dihydroxypyrimidines. Antimicrob. Agents Chemother. 2010, 54, 977– 983. (335) Leonard, D. M. Ras farnesyltransferase: a new therapeutic target. J. Med. Chem. 1997, 40, 2971–2990. (336) Singh, S. B.; Zink, D. L.; Liesch, J. M.; Goetz, M. A.; Jenkins, R. G.; Nallin-Omstead, M.; Silverman, K. C.; Bills, G. F.; Misley, R. T. Isolation and structure of chaetomellic acids A and B from Chaetomella acutiseta: farnesyl pyrophosphate mimic inhibitors of Ras farnesylprotein transferase. Tetrahedron 1993, 49, 5917–5926. (337) Weaver, R.; Gilbert, I. H.; Mahmood, N.; Balzarini, J. Isosteres of nucleoside triphosphates. Bioorg. Med. Chem. Lett. 1996, 6, 2405–2410. (338) Weaver, R.; Gilbert, I. H. The design and synthesis of nucleoside triphosphate isosteres as potential inhibitors of HIV reverse transcriptase. Tetrahedron 1997, 53, 5537–5562. (339) Herdewijn, P.; Marliere, P. Toward safe genetically modified organisms through the chemical diversification of nucleic acids. Chem. Biodiversity 2009, 6, 791–808. (340) Adelfinskaya, O.; Herdewijn, P. Amino acid phosphoramidate nucleotides as alternative substrates for HIV-1 reverse transcriptase. Angew. Chem., Int. Ed. 2007, 46, 4356–4358. (341) Adelfinskaya, O.; Terrazas, M.; Froeyen, M.; Marliere, P.; Nauwelaerts, K.; Herdewijn, P. Polymerase-catalyzed synthesis of DNA from phosphoramidate conjugates of deoxynucleotides and amino acids. Nucleic Acids Res. 2007, 35, 5060–5072. (342) Terrazas, M.; Marliere, P.; Herdewijn, P. Enzymatically catalyzed DNA synthesis using L-Asp-dGMP, L-Asp-dCMP, and L-Asp-dTMP. Chem. Biodiversity 2008, 5, 31–39. (343) Zlatev, I.; Giraut, A.; Morvan, F.; Herdewijn, P.; Vasseur, J.-J. δ-Di-carboxybutyl phosphoramidate of 20 -deoxycytidine-50 -monophosphate as substrate for DNA polymerization by HIV-1 reverse transcriptase. Bioorg. Med. Chem. 2009, 17, 7008–7014. (344) Giraut, A.; Herdewijn, P. Influence of the linkage between leaving group and nucleoside on substrate efficiency for incorporation in DNA catalyzed by reverse transcriptase. ChemBioChem 2010, 11, 1399– 1403. (345) Giraut, A.; Song, X.-P.; Froeyen, M.; Marliere, P.; Herdewijn, P. Iminodiacetic-phosphoramidates as metabolic prototypes for diversifying nucleic acid polymerization in vivo. Nucleic Acids Res. 2010, 38, 2541–2550. (346) Yang, S.; Froeyen, M.; Lescrinier, E.; Marliere, P.; Herdewijn, P. 3-Phosphono-L-alanine as pyrophosphate mimic for DNA synthesis using HIV-1 reverse transcriptase. Org. Biomol. Chem. 2011, 9, 111–119. (347) Giraut, A.; Dyubankova, N.; Song, X.-P.; Herdewijn, P. Phosphodiester substrates for incorporation of nucleotides in DNA using HIV-1 reverse transcriptase. ChemBioChem 2009, 10, 2246–2252. (348) Koide, K.; Bunnage, M. E.; Gomez Paloma, L.; Kanter, J. R.; Taylor, S. S.; Brunton, L. L.; Nicolaou, K. C. Molecular design and biological activity of potent and selective protein kinase inhibitors related to balanol. Chem. Biol. 1995, 2, 601–608. (349) Narayana, N.; Diller, T. C.; Koide, K.; Bunnage, M. E.; Nicolaou, K. C.; Brunton, L. L.; Xuong, N.-H.; Ten Eyck, L. F.; Taylor, S. S. Crystal structure of the potent natural product inhibitor balanol in complex with the catalytic subunit of cAMP-dependent protein kinase. Biochemistry 1999, 38, 2367–2376. (350) Tesmer, J. J. G.; Tesmer, V. M.; Lodowski, D. T.; Steinhagen, H.; Huber, J. Structure of human G protein-coupled receptor kinase 2 in complex with the kinase inhibitor balanol. J. Med. Chem. 2010, 53, 1867–1870. 2590 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591 Journal of Medicinal Chemistry (351) Pudlo, J. S.; Cao, X.; Swaminathan, S.; Matteucci, M. D. Oligodeoxyribonucleotides containing 20 ,50 acetal linkages: synthesis and hybridization properties. Tetrahedron Lett. 1994, 35, 9315–9318. (352) Lin, K.-Y.; Matteucci, M. D. The synthesis and hybridization properties of an oligonucleotide containing hexafluoroacetone ketal internucleotide linkages. Tetrahedron Lett. 1996, 37, 8667–8670. (353) Zou, R.; Matteucci, M. D. Synthesis and hybridization properties of an oligonucleotide analog containing a glucose-derived conformation-restricted ribose moiety and 20 ,50 formacetal linkages. Tetrahedron Lett. 1996, 37, 941–944. (354) Goldring, A. O.; Gilbert, I. H.; Mahmood, N.; Balzarini, J. Lipophilic bio-isosteres of nucleoside triphosphates. Bioorg. Med. Chem. Lett. 1996, 6, 2411–2416. (355) Goldring, A. O.; Balzarini, J.; Gilbert, I. H. Design and synthesis of bio-isosteres of thymidine triphosphate. Bioorg. Med. Chem. Lett. 1998, 8, 1211–1214. (356) Otoski, R. M.; Wilcox, C. S. An approach to lipophilic nucleotide phosphate analogs. Synthesis of a lipophilic isostere of ATP. Tetrahedron Lett. 1988, 29, 2615–2618. (357) Ladbury, J. E.; Klebe, G.; Freire, E. Adding calorimetric data to decision making in lead discovery: a hot tip. Nat. Rev. Drug Discovery 2010, 9, 23–27. (358) Michel, J.; Tirado-Rives, J.; Jorgensen, W. L. Energetics of displacing water molecules from protein binding sites: consequences for ligand optimization. J. Am. Chem. Soc. 2009, 131, 15403–15411. (359) Lam, P. Y. S.; Jadhav, P. K.; Eyermann, C. J.; Hodge, C. N.; Ru, Y.; Bacheler, L. T.; Meek, J. L.; Otto, M. J.; Rayner, M. M.; Wong, Y. N.; Chang, C.-H.; Weber, P. C.; Jackson, D. A.; Sharpe, T. R.; EriksonViitanen, S. Rational design of potent, bioavailable, nonpeptide cyclic ureas as HIV protease inhibitors. Science 1994, 263, 380–384. (360) Lam, P. Y. S.; Ru, Y.; Jadhav, P. K.; Aldrich, P. E.; DeLucca, G. V.; Eyermann, C. J.; Chang, C.-H.; Emmett, G.; Holler, E. R.; Daneker, W. F.; Li, L.; Confalone, P. N.; McHugh, R. J.; Han, Q.; Li, R.; Markwalder, J. A.; Seitz, S. P.; Sharpe, T. R.; Bacheler, L. T.; Rayner, M. M.; Klabe, R. M.; Shum, L.; Winslow, D. L.; Kornhauser, D. M.; Jackson, D. A.; Erickson-Viitanen, S.; Hodge, C. N. Cyclic HIV protease inhibitors: synthesis, conformational analysis, P2/P20 structure-activity relationship, and molecular recognition of cyclic ureas. J. Med. Chem. 1996, 39, 3514–3525. (361) De Lucca, G. V.; Erickson-Viitanen, S.; Lam, P. Y. S. Cyclic HIV protease inhibitors capable of displacing the active site structural water molecule. Drug Discovery Today 1997, 2, 6–18. (362) Nalam, M. N. L.; Peeters, A.; Jonckers, T. M. H.; Dierynck, I.; Schiffer, C. A. Crystal structure of lysine sulfonamide inhibitor reveals the displacement of the conserved flap water molecule in human immunodeficiency virus type 1 protease. J. Virol. 2007, 81, 9512–9518. (363) Canan Koch, S. S.; Thoresen, L. H.; Tikhe, J. G.; Maegley, K. A.; Almassy, R. J.; Li, J.; Yu, X.-H.; Zook, S. E.; Kumpf, R. A.; Zhang, C.; Boritzki, T. J.; Mansour, R. N.; Zhang, K. E.; Ekker, A.; Calabrese, C. R.; Curtin, N. J.; Kyle, S.; Thomas, H. D.; Wang, L.-Z.; Calvert, A. H.; Golding, B. T.; Griffin, R. J.; Newell, D. R.; Webber, S. E.; Hostomsky, Z. Novel tricyclic poly(ADP-ribose) polymerase-1 inhibitors with potent anticancer chemopotentiating activity: design, synthesis, and X-ray cocrystal structure. J. Med. Chem. 2002, 45, 4961–4974. (364) Tikhe, J. G.; Webber, S. E.; Hostomsky, Z.; Maegley, K. A.; Ekkers, A.; Li, J.; Yu, X.-H.; Almassy, R. J.; Kumpf, R. A.; Boritzki, T. J.; Zhang, C.; Calabrese, C. R.; Curtin, N. J.; Kyle, S.; Thomas, H. D.; Wang, L.-Z.; Calvert, A. H.; Golding, B. T.; Griffin, R. J.; Newell, D. R. Design, synthesis, and evaluation of 3,4-dihydro-2H-[1,4]diazepino[6,7,1-hi]indol-1-ones as inhibitors of poly(ADP-ribose) polymerase. J. Med. Chem. 2004, 47, 5467–5481. (365) García-Sosa, A. T.; Firth-Clark, S.; Mancera, R. L. Including tightly-bound water molecules in de novo drug design. Exemplification through in silico generation of poly(ADP-ribose)polymerase inhibitors. J. Chem. Inf. Model. 2005, 45, 624–633. (366) Chen, J. M.; Xu, S. L.; Wawrzak, Z.; Basarab, G. S.; Jordan, D. B. Structure-based design of potent inhibitors of scytalone PERSPECTIVE dehydratase: displacement of a water molecule from the active site. Biochemistry 1998, 37, 17735–17744. (367) Liu, C.; Wrobleski, S. T.; Lin, J.; Ahmed, G.; Metzger, A.; Wityak, J.; Gillooly, K. M.; Shuster, D. J.; McIntyre, K. W.; Pitt, S.; Shen, D. R.; Zhang, R. F.; Zhang, H.; Doweyko, A. M.; Diller, D.; Henderson, I.; Barrish, J. C.; Dodd, J. H.; Schieven, G. L.; Leftheris, K. 5-Cyanopyrimidine derivatives as a novel class of potent, selective, and orally active inhibitors of p38R MAP kinase. J. Med. Chem. 2005, 48, 6261–6270. (368) Wissner, A.; Berger, D. M.; Boschelli, D. H.; Floyd, M. B., Jr.; Greenberger, L. M.; Gruber, B. C.; Johnson, B. D.; Mamuya, N.; Nilakantan, R.; Reich, M. F.; Shen, R.; Tsou, H.-R.; Upeslacis, E.; Wang, Y. F.; Wu, B.; Ye, F.; Zhang, N. 4-Anilino-6,7-dialkoxyquinoline-3carbonitrile inhibitors of epidermal growth factor receptor kinase and their bioisosteric relationship to the 4-anilino-6,7-dialkoxyquinazoline inhibitors. J. Med. Chem. 2000, 43, 3244–3256. 2591 dx.doi.org/10.1021/jm1013693 |J. Med. Chem. 2011, 54, 2529–2591